JP2013119789A - Various energy preserving cycle united engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem of existing steam turbine power generation in which a steam speed is reduced to 1/10 by damming up the steam speed by having stator blades which are nil in power factor by a half, a maximum speed part is 43,000 times volume of water, and a power generation output is almost zero.SOLUTION: A power generation quantity of 1/10 or smaller by damming up a lightweight steam speed by including the stator blades which are nil in the power factor by a half, and lightweight object power generation is improved to provide an electricity+liquid air+superheated steam hot heat supply facility 3D for generating sunlight heater heat for inexpensive electric driving such as a power generation cost of 1/100 such as a fuel cost 0 by aiming at 0 of a power generation quantity bearing load of existing 100 times in a one unit power generation quantity of superposing 100 sets of water injection turbines by aiming at Mach 30 as water gravity acceleration power generation in a 30 mmHg vacuum for doubly reversing the whole moving blades by a horizontal shaft 1h gear, an automobile, a ship and an aircraft are set in a volume compression power of 21/60,000 of air compression as liquid oxygen compression driving, and set in 1/10 fuel cost and a 10-time speed, the aircraft is aimed at 1/500,000 space arrival cost so as to enable a day' trip anywhere on the earth, and thus an operational profit for operating the whole manufacturing object becomes preeminently and permanently best in the world.

Description

The present invention is a vertical all-blade hydrogravity turbine 8P power generation in which six types of annular turbine blade groups are fitted to the Mach 30 water drive with liquid jet velocity + gravity acceleration in vacuum, and an internal and external cylindrical shaft device aiming at ultra-high circumferential speed. The repulsive permanent magnet 9B + attractive permanent magnet 9C brings the bearing load close to 0 and an ultra-high speed peripheral speed, and the gear reversal magnetic device 85 + reversed one after another by the horizontal axis 1h to the vibration reduction head 828m. For example, Mach 28 is added to the existing pumped-storage power generation that generates turbines such as 100 units, adding the gravitational acceleration during the increase in the vacuum degree to the existing pumped-storage power generation, adding Mach 3 or more high-speed injection + unlimited number of turbines, and unlimited head Water jet vacuum acceleration in the target, aiming for 800 times the amount of power generation of existing pumped-storage power generation such as 100 sets of turbines with a head of 500-828m, fuel cost of boilers and nuclear reactors abolished 0 resource price 0 experiment is necessary Water-gravity turbine 8M power generation electric drive 1 to multistage heat pump 1G or solar heater 21, and solar heating air is compressed to high temperature, and heat recovery is divided and stored by 1 to multistage compression heat recovery unit 2C. 24 to 200MPa superheated steam 50 warm heat + liquid air 28a cold heat, divided into electricity + liquid air cold heat + superheated steam heat supply equipment 3D endless application, for example, ships, vehicles and airplanes are liquid oxygen The compression volume work rate is set to 21/60000 volume work rate of air compression, the compression pressure of liquid oxygen or water is made 20 times easier, the rotational force drive of the theoretical expansion engine 3Q, or the oxygen combined air injection unit 88B and oxygen coalescence water injection unit 88L are united injection propulsion, and ship coalescence injection propulsion is a natural phenomenon speeding up 2a Supply nitrogen, oxygen and CO2 to seawater Increase microorganisms and seaweed, The human food such as fish is greatly increased, etc., and the driving of airplanes and automobiles aims to reach 1/10 of CO2 exhaust, 1/10 of the fuel cost and 1 / 500,000 cost space, and 10 times the speed of airplanes and ships, and save various energy The present invention relates to a technology of a cycle coalescence engine and various energy storage coalescence methods.

  The world's largest automobile driven reciprocating engine consumes enormous amount of fuel due to air compression. Electric + liquid air cold heat + superheated steam heat supply equipment of vertical type rotor blade water gravity turbine 8P vacuum water gravity acceleration power generation electric manufacturing Supply as 3D, for example, superheated steam is injected into methane hydrate under permafrost land or underwater, methane and water are divided into methane and recovered as liquid nitrogen cooled liquid methane, liquid oxygen chamber 5K receives liquid oxygen 5K and liquid oxygen 5K compression, compression volume work rate is 21/60000 volume work of air compression, 24-200MPa ultra high pressure compression injection, liquid oxygen 5K + liquid fuel 1b + high temperature water 52a to ultra high pressure in compression theoretical combustion chamber 4Q The fuel is injected and burned in the process of heating at the circumference, etc., and injecting each into the theoretical combustion chamber 4Q by heating to an ultra-high temperature or optimum temperature, and ultra-high pressure oxygen + ultra-high pressure fuel at high temperature combustion. Pressure high temperature superheated steam 50 is heated, and super high pressure oxygen super high pressure fuel flame 3000 ° C or more Pyrolysis electrolysis of superheated steam aims at various researches of oxygen hydrogen augmentation combustion, super high pressure combustion gas 49 + superheated steam in theoretical combustion chamber 4Q 50, the high-pressure high-temperature combustion gas control valve 5a is opened and injected from the combustion gas injection nozzle 6Y to drive the theoretical expansion engine 3Q to drive various vehicles such as automobiles and tillers, propellers 7A, rotor blades 7B, and screws 7C. And driving various vehicles, propeller airplanes and screw ships, aiming at fuel cost 1/10 or 10 times speed by using liquid oxygen 5K of electricity generation electricity generation, various energy aiming at the world's best operating profit rate The present invention relates to a storage cycle coalescence engine and a coalescence technique.

  The existing jet gas turbine consumes enormous amount of fuel by air compression, and the rotation output and injection propulsion output are reduced, and space flight such as 16 rounds of the earth on the day of the air resistance 01 is impossible by air compression. As an aim of propulsion of the liquid compressed oxygen coalesced air injection unit 88B, which is a combination of the two-stage theoretical gas compressor 3T isothermal pump 1G + solar heater 21 heat By manufacturing, it is divided and stored in high-temperature water of 24-200 MPa to superheated steam temperature 50 + liquid air cold heat 28a, and as an electric + liquid air cold heat + superheated steam heat supply facility 3D, the jet injection propulsion is liquid oxygen 5K + liquid fuel 1c + high temperature water. 52a, the compressed volumetric power is compressed by liquid oxygen compression, and the compressed oxygen volume is 21/60000 volumetric power ultra-high pressure compressed by liquid compression. The water control valve 5Q + liquid fuel control valve 1K is opened, and each is set to an optimum heating temperature by the fuel heating pipe 1L water heating pipe 5H oxygen heating pipe 5H in the inner periphery of the oxygen combined air injection section 88B theoretical combustion chamber 4Q, and the fuel control valve 25b + The oxygen control valve 24D + superheated steam control valve 25 is opened, and each of them is injected and burned into a theoretical combustion chamber 4Q aiming at one or more theoretical ultra-high pressure combustion, and the oxygen injection nozzle 6L fuel injection nozzle 6X multiple central combustion at 3300 ° C or higher thermal decomposition As an electrolysis target, superheated steam aims to increase oxygen-hydrogen combustion + air in front of rocket combustion is sucked and injected, and 1 to multiple-stage suction airflow jet combustion is added, theoretical combustion chamber 4Q superheated steam injection nozzle 6A superheated steam 50 With a 200MPa target injection, the combustion gas 49 is sucked and injected. With rocket combustion, the space arrival cost is aimed at 1 / 500,000. To anywhere on Earth etc. for 16 laps the earth to allow a day trip, aimed at profit margins preeminent world in a variety of space shuttle airplane class, relates to a technology of various energy conservation cycle combined institutions and coalescence method.

  The existing ship consumes a large amount of fuel by air compression, reduces the rotational output and injection propulsion output, and consumes a large amount of fuel for low-speed movement. / 60000 volumetric power, liquid air production air compressor is also theoretically best theoretical gas compressor 3T addition, vertical full blade water gravity turbine 8P power generation electric drive 1-multistage theoretical gas compressor 3T etc. As the heat pump 1G compression, the solar heating air 21 is heated to a compressed high temperature, and the heat production is divided and stored in the 1-multistage compression heat recovery unit 2C. 50M + liquid air 28a cold and stored separately, as electricity + liquid air cold + superheated steam temperature supply equipment 3D, liquid oxygen 5K + liquid fuel 1c + high temperature water 52a pump compression 200M in the process of receiving a Aiming, the liquid oxygen control valve 5T + liquid fuel control valve 1K + water control valve 5Q are opened and heated to the optimum temperature in the inner periphery of the oxygen combined water injection part 88L theoretical combustion chamber 4Q, respectively. Each of the injections to the theoretical expansion engine 3Q is driven by water suction injection or rotationally driven to promote water suction / injection propulsion of the oxygen combined water injection unit 88L or to rotate the screw 7C of the theoretical expansion engine 3Q. / 10 As a fuel cost target, the screw propulsion theoretical expansion engine 3Q exhaust will be the bottom bottom exhaust injection propulsion, the natural phenomenon speeded up in the process of friction reduction injection propulsion, supplying oxygen, nitrogen, CO2 etc. into the sea, The present invention relates to technologies for various energy conservation cycle coalescence engines and coalescence methods that increase phytoplankton, seaweeds, corals, fish, etc., and increase the food of human beings, aiming at the world's highest profit rate.

  Considering elementary school science without brainwashing, the existing best steam turbine power generation at atmospheric pressure and speed and volumetric capacity kg weight m / sec is a little less than 1/1700 of vertical all-blade water gravity turbine 8P power efficiency. Since the steam velocity is dammed and the stationary vanes with no work are alternately dammed with the moving blades, the vapor velocity is close to 1/100 and the gas volume is inversely proportional to the pressure. Because it requires a turbine blade that can handle up to 240 times volume up to atmospheric pressure +30 and 4 times Hg, up to 4 times Hg, it can handle up to 6000 times volume. Theoretically, the high-pressure steam speed is unreasonable and there is a background that requires a revolution. In addition to responding to the turbine blade area, the seawater temperature is raised by 7 degrees with all the generated heat, making the whole sea surface temperature-increasing natural phenomenon, increasing abnormal weather without upper limit, and by heavy rain of seawater around 50 to 100 years Mankind is near extinction Ku is in increasing danger. The green earth is a miracle product and there is a great risk of approaching other stars. According to the explanation of the power station, if the rise in seawater temperature is 7 degrees or less, there is no influence on the environment, but for example, 7 degrees in the sea area where the seawater temperature is 30 degrees If the rise continues, the typhoon wind speed will be 300m / sec, etc., and there will be danger of human beings extinction due to the covering of concentrated rainwater salt in seawater, etc., and the temperature of the whole sea surface will rise and nutrients such as nitrogen, oxygen, CO2 etc. The natural phenomenon that has supplied water is made impossible, the number of marine microorganisms, phytoplankton and seagrass is drastically reduced. The number of marine foods such as fish is drastically reduced. If China continues to grow 10%, the rise in seawater temperature will be 10%. The current rate is twice as high as the current rate in 20 years, and the speed of typhoons, seasonal winds and ocean tornadoes is 100m / sec. And forestry and residential areas Such as close to 0, for Japan residents it is difficult before and after 50 years, there is a background necessary technical development that corresponds to the existing technologies worst part before it's too late.

When the atmospheric pressure, the same speed, and the same volumetric power, kg weight m / sec, are set to 1700 times the water power of the existing steam turbine power generation, and the water gravity acceleration power generation in the vacuum, the same speed 1/100 volumetric power will be the existing steam turbine power generation. The power generation is 17 times higher than that of the previous generation, but a huge amount of power generation such as 1700 times power generation is expected in 100 pairs at a height of 500 m or more, the water resources are enormous, and if deep sea water is used, there are many by-products and further experiments are required The water gravity acceleration in the vacuum Mach 30 is aimed at infinite power generation with a fuel cost of 0 power generation, and the cylindrical assembly fixed rotor blade group is formed as a vertical all-water blade water gravity turbine 8P power generation cylinder inner blade group 60C cylinder outer blade group 60D. Including fully automatic machining, easy assembly, 1/10 number of parts, 100 times assembly of 1/10 parts, aiming for 1700 times power generation, aiming for the world's largest gravity acceleration acceleration in vacuum Mach 30 gravity It is driven by energy, and it shifts to the expansion of the use of low-cost electricity with zero fuel cost generation with a large amount of cheap water resources, solar heating the air by the solar heater 21, and water gravity turbine 8M fuel cost zero power generation electric drive , 1-multistage theoretical gas compressor 3T, etc., compressed multiple times with heat pump 1G, recovered heat multiple times, 24-200MPa high temperature water 52a-superheated steam temperature 50 + liquid air cold heat 28a, divided and stored, electricity + liquid air cold heat + Supply from the superheated steam temperature supply facility 3D, and receive it to the liquid oxygen chamber 5K, storage battery, etc., make liquid air driven cars, airplanes and ships 1/10 fuel cost drive or 10 times speed drive, extremely inexpensive There is a background that can be achieved such as storage battery drive and electric drive for simple power generation, and prevention of global warming with little CO2 exhaust.

  In high school and university, the existing engine is described as the best engine, and when we return to elementary school science without brainwashing and think about the best engine, the unit of work is kg weight m / sec. The engine is the best engine in terms of generating rotational output at a high speed, but there is no trace of thought. Therefore, for example, when a vertical full-blade hydrogravity turbine 8P power generation is used, there is a background that the fuel cost is low and the power generation is low, and the case of heating an enormous amount of methane hydrate sleeping in the sea near Japan or permafrost is considered as a fuel in elementary school science. Cost 0 heating is the best. Therefore, the fuel cost 0 power generation electric drive solar heater 21 is used, and the heat pump 1G such as the 1-multistage theoretical gas compressor 3T or the 1-multiple stage compression of the air 28a heated by sunlight with the fuel cost 0 power generation electric drive is used. In the heat recovery unit 2C, the heat is recovered multiple times and heat is recovered multiple times, divided into 5K cold liquid oxygen and 5L liquid nitrogen + hot high temperature water 52a to superheated steam 50, and in the process of infinite use of heat, for example permafrost Injecting superheated steam 50 into underground methane hydrate, splitting it into methane and water, recovering methane with liquid nitrogen cooled liquid methane and continuing the superheated steam injection forever, the methane recovery enclosure has a suitable temperature and lots of water droplets Land grazing, increasing the use of food by humans, and infinite use of heat, aiming to reach 1 / 500,000 in space-driven costs for liquid air-powered cars, ships and spacecrafts, and speeding natural phenomena in the process of ship driving 2a , Fine And the seaweed and coral, etc. to increase the food of fish such as the human race in the growth the food chain, etc., to prevent the heavy rain of sea water there is a background that can put off the human race extinct. Revolution of employment growth that will increase the employment by making the manufacturing operation monopolized 100% worldwide, with the operating profit rate becoming 10 times larger than the existing operational profit ratio, as the ship revolution and airplane revolution aiming at 10 times speed with low fuel cost There is a background that can be.

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PCT International Application Publication No. WO 2010/101017 PCT / JP2010 / 052171 etc. have 326 applications from the date of filing of Japanese Patent Application No. 2009-048869 on March 3, 2009 to the date of filing of Japanese Patent Application No. 2010-007805 on January 18, 2010 Since then, there have been 19 applications, including PCT, from the application date of Japanese Patent Application No. 2011-247103 to November 11, 2011.

  In the existing thermal power plants in the world, the total heat generation is 7 degrees Celsius, and the seawater temperature rise is 1000 times in 100 years, and the downdrafts and updrafts are increased as much as possible. As the number of storms, torrential rains, heat waves, cold waves, etc. increases without limit, typhoons, seasonal winds, tornadoes, etc., around 100 years in the sea near Japan, salt water on the land due to concentrated heavy rains, etc. Covering increases the danger of human land food loss, making it impossible for the natural phenomenon of supplying nutrients to the sea-cooled seabed in winter, dramatically reducing microorganisms, phytoplankton, seaweeds, corals, etc., fish through food chains, etc. The number of human underwater foods has been reduced as much as 1/100, and droughts, torrential rains, typhoons and seasonal winds have increased 10 times in 100 years. For example, typhoons and seasonal winds have an upper limit such as 300m / sec. weather Giant seafloor bedrock expansion earthquakes and tsunamis, and eastern Japan earthquakes and tsunamis have also become huge, preventing heavy rain in seawater to increase the danger of human extinction, preventing global warming such as rising seawater temperature, There is a challenge to postpone human extinction. A recent issue is the rapid increase in countries with deficits. The biggest cause is the epidemic that easily makes profits with low labor cost countries as the world's factories, and all the developing countries that can easily make profits compete for the best in imitation improvement like Japan in the past, so cheap and excellent products There is a risk of the destruction of manufacturing facilities in the developed countries and the deficit of jobs in the developed countries, and the destruction of employment.There is an urgent need to increase profit margins in developed countries because the current economic crisis is in the early stages. However, as a top-secret manufacturing operation of the invention that keeps 100% monopoly on the world scale forever, there is a challenge to make the world's most eternal financial surplus with outstanding profitability forever.

A vertical all blade hydrogravity turbine 8P fuel cost 0 power generation cheap electric drive all, heat production by solar heater 21 + 1-multistage theoretical gas compressor 3T etc. heat pump 1G + 1-multistage compression heat recovery unit 2C, Electricity + liquid air cooling + hot water to superheated steam temperature supply equipment 3D compresses the received liquid oxygen 5K to 21/60000 volumetric compression work rate of air compression, theoretical combustion that is easy for ultra high pressure combustion and ultra high temperature combustion As the chamber 4Q, the high-pressure high-temperature superheated steam 50 is heated by combustion near the center of the oxygen fuel ultra-high pressure combustion, and the oxygen-hydrogen super-high pressure combustion flame is aimed at pyrolysis electrolysis of the superheated steam at 3000 ° C or more, aiming at oxygen-hydrogen-enhanced combustion, The theoretical expansion engine 3Q driven by the theoretical combustion chamber 4Q, the oxygen combined water injection unit 88L, and the oxygen combined air injection unit 88B are used to drive vehicles such as automobiles, ships, and airplanes, and to drive the rotational force or perform the injection propulsion. The ship jet propulsion drive speeds up natural phenomena 2a, supplies oxygen, nitrogen, CO2, etc. into the sea, increases microorganisms, phytoplankton, seaweeds, corals, fish, etc. Assuming that the Earth will fly 16 times a day in the heyday of space flight close to zero CO2 exhaust, etc., it is aimed at day trips everywhere on the earth and the CO2 exhaust is a little flight aiming at the air, 100% global scale monopoly power generation that operates in secret Global warming by making the world the best in profitability and the best in new employment as a ship, ship, airplane, car, etc., preventing droughts, torrential rains, typhoons, seasonal winds, heavy rains in seawater and earthquakes and tsunamis Prevent and delay human extinction.

A vertical all-blade hydrogravity turbine 8P has a very large effect of transmitting the horizontal axis 1h double reversal to 100 sets, etc., with low fuel cost, low fuel cost generation, and the best turbine blade 8c of two types of cylindrical blade groups 60C60D. The 100-unit manufacturing effect is 100% by fully automatic manufacturing, and the effect of simplifying the structure without the need of a boiler or nuclear reactor is also very large. The water gravity turbine 8P power generation is compared with the maximum speed of the last moving blade group in the same vacuum drive. When the atmospheric pressure is 100 ° C. and 760 mmHg, the water vapor of 1,700 times the volume of water is exhausted at 29 ° C. and the degree of vacuum is 30 mmHg. 760mmHg × 1700 = 30mmHg × V2 volume water vapor, V2 = 760/30 × 1700 = water 43,000 times volume water vapor, 1/100 volume water power generation 4 It becomes 0 times amount of power generation. In other words, vertical all-blade water gravity turbine 8P power generation, which is a group of existing steam turbine maximum speed power blades, is much more advantageous at the power generation stage, and 430 times power generation at 1/100 volume water speed of superheated steam. In addition to increasing the amount, the degree of vacuum increase is far superior, and the use of gravitational acceleration in the vacuum is further increased to 43,000 times the power generation amount calculated by one set of 100 pairs, water injection speed Mach 3 × in vacuum Experiments are necessary, such as gravitational acceleration = Mach 30 aiming to further increase the power generation amount by 30 times, but it has the effect of greatly reforming the power generation cost to 1/10 etc. and infinitely increasing the employment of electrical products.

The green earth is a miracle product and has a high risk of approaching other stars. For example, if China continues to grow 10% for 100 years, the temperature rise in the sea near China will exceed 1000 times due to thermal power generation and nuclear power generation. There is a strong possibility that the extinction of mankind will rapidly approach within 100 years, such as the increase in guerrilla heavy rain in Japan is 1000 times the heavy rain in seawater, the current drastic decrease in fish is close to 0, and seawater temperature rises 0, CO2 emissions 0 and fuel costs 0 Electric power drive is required. Therefore, the fuel cost is 0. Electricity generated by power generation + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment 3D receives liquid oxygen 5K, etc., and the compression work rate of combustion oxygen is 21/60000 volumetric compression work of air compression The theoretical combustion chamber 4Q uses the theoretical expansion engine 3Q, the oxygen coalescence water injection unit 88L, and the oxygen coalescence air injection as an aim to increase the superhigh pressure superheated steam 50 in the superficial combustion chamber 4Q center and increase the pyrolysis electrolysis. Part 88B has the effect of being able to drive the most efficiently, and in addition to the effect of targeting 1/10 or 10 times the fuel cost of automobiles, ships and airplanes, the space arrival cost is aimed at 1 / 500,000 of existing space rockets The wheel, screw 7C, propeller 7A and rotor blade 7B are driven by the theoretical expansion engine 3Q, and the ship, airplane, car, etc. are driven by the rotational force, and the ship injection propulsion drive is used. Natural phenomenon speeding up 2a, and the effect of increasing the digestive capacity of underwater microorganisms such as CO2 to tens of thousands of times of the forest, etc. is great, and phytoplankton, seaweeds, corals, etc. are propagated, and fish and other human beings in the food chain etc. Greatly increase undersea food, prevent desertification, droughts, torrential rains, typhoons, seasonal winds, earthquake tsunamis, etc., postpone the most important human extinction of humanity, and aim to achieve the world's best profit rate is there.

Plane drive receives liquid oxygen hot water from electricity + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment, which is driven by electric power of 0mm type all-blade water gravity turbine 8P power generation, liquid oxygen 5K + liquid fuel 1c + The high temperature water 52a is compressed by ultra high pressure by the liquid fuel pump 4a + liquid oxygen pump 4b + water pump 4c, the liquid fuel control valve 1K + liquid oxygen control valve 5T + water control valve 5Q is opened, and fuel heating in the inner periphery of the theoretical combustion chamber 4Q The pipe 1L + the oxygen heating pipe 5F + the high-temperature water heating pipe 5H is optimally heated to open the fuel control valve 25b, the oxygen control valve 24D, and the mixed injection ignition combustion is performed in the vicinity of the center of the oxygen gas + fuel gas plural places, in the theoretical combustion chamber 4Q The surrounding fuel heating pipe 1L + oxygen heating pipe 5F + high temperature water heating pipe 5H is optimally heated and superheated to super high pressure high temperature superheated steam 50, etc., and theoretical combustion chamber 4Q superheated steam pyrolysis with maximum temperature super high pressure combustion Aiming at combustion with oxygen and hydrogen increased combustion, driving the oxygen coalesced air injection unit 88B, aiming for space arrival cost 1 / 500,000 of existing space rockets, and fueling the use of space with the same fuel cost 10 times injection propulsion output For example, the jet propulsion output is aimed at 100 times the pressure of existing jets, 10 times the calorie injection, and 1000 times the propulsion output for the short time. Since the injection speed and combustion gas injection speed are the highest in vacuum, the existing ground rocket ground mass injection is considered the worst, and the injection amount of high pressure high temperature combustion gas 5M + high pressure high temperature steam 5N of 24-200MPa from the vicinity of the highest flight altitude of the existing aircraft The effect is to increase the space use prime that allows you to take a day trip anywhere on the earth, such as 16 rounds of the earth per day.

Explanatory drawing of 1h9C9B of vertical type moving blade water gravity turbine 8P (Example 1) Explanatory drawing of 60E60F60G60H of cylindrical blade group 60C60D (Example 2) Explanatory drawing of the solar heater 21 of electricity + liquid cold / heat supply equipment 3D (Example 3) Explanatory drawing of 9B9C9D9E6F6G6H of theoretical gas compressor 3T (Example 4) Explanatory drawing of 5b6X6Y9B9C9D9E5 of theoretical expansion engine 3Q (Example 5) Explanatory drawing of oxygen combined water injection part 88L (Example 6) Explanatory drawing of the oxygen coalescence air injection part 88B (Example 7) Explanatory drawing of the theoretical expansion locomotive 4L (Example 8) Explanatory drawing of oxygen coalescence screw ship 39Q (Example 9) Explanatory drawing of the oxygen coalescence screw injection ship 39S (Example 10) Explanatory drawing of oxygen coalescence injection ship 39R (Example 11) Explanatory drawing of the oxygen coalescence injection plane 39T (Example 12) Explanatory drawing of oxygen combined propeller plane 39U (Example 13)

  The use of gravity acceleration in vacuum for a long period of time is prevented by brainwashing such as existing steam turbine power generation, and one unit of 100 sets prevents the aim of generating power 43,000 times that of one existing steam turbine power generation, for example, the existing best steam turbine power generation Steam pressure is reduced by reducing the atmospheric pressure, the same speed, and the same volumetric power, kg weight m / second, to 1/1700 of the water power, and by installing the stationary blades alternately with the moving blades and blocking the rotation output to zero. The seawater temperature rises by 7 degrees with all of the driving heat of the sea, the fishes drastically decrease, the bottom bedrock expands into earthquakes and tsunamis, and the typhoons, seasonal winds and sea tornadoes around Japan are increased to around 100 m / sec. There is a danger that food extinctions and humankind extinction will be approaching rapidly by providing salt coating on the land in around 50 to 100 years, such as heavy rain of suction seawater is expected over the sea. That is, since the invention becomes too large due to many fatal defects of the existing technology, the description of the invention is described in the description of the reference, and the part which has been repeatedly described in the previous application is omitted, and the horizontal axis 1h counter-rotating vertical type whole moving blade We will challenge the realization of the invention which omits common sense by substituting three types of examples other than the water gravity turbine 8P.

FIG. 1 Since the vertical power blade hydrogravity turbine 8P power generation aiming at the limit such as Mach 30 drive with gravity acceleration in water + water injection speed, the power generation amount is proportional to kg weight m / second, so the inner shaft device 60A outer shaft device 60B is provided with a repulsive permanent magnet 9B and an attractive permanent magnet 9C, respectively, the bearing load is made close to 0 by the repulsive force and the attractive force, and there are a plurality of ring-type double-sided two-pole magnetized rotation speeds and rotational outer diameters. Aiming at an infinite increase, water 3E is raised by 500 to 828 m, etc. by the specific critical material raising device 2F, and the water is driven by the specific critical material accelerator 6W to aim at the acceleration of gravity acceleration Mach 30 in the water 3E vacuum. 60C cylindrical outer rotor blade group 60D Super high speed turbine peripheral speed record update aiming at vertical power rotor hydrogravity turbine 8P power generation driven 100 pairs etc. one after the other by double inversion with horizontal shaft 1h gear, outside inner shaft device 60A Shaft 60B is equipped with a cylindrical part, making full-automatic machining and assembly easy, and moving blade group fitted to the cylindrical annular assembly 9A, driven by 1h inversion on the horizontal axis, and the air extractor 51 dedicated to gas In the manufacturing process, the frictional heat of the water contained in the cooling chamber 11D is set to the highest vacuum, and in the manufacturing process, the six parts shown in FIG. 2 are respectively replaced with the inlet fixed outer blade 60E + the inlet fixed inner blade 60F +. The outer annular blade 60G + the inner annular blade 60H + the outlet fixed outer blade 60J + the outlet fixed inner blade 60K, each of which is made of 100 parts by fully automatic casting, fully automatic processing, cemented carbide surface treatment, etc. Equipped with a gravity acceleration part 1g for vacuum acceleration of water as a thrust bearing 80a and bearing 80 including permanent magnets and electromagnets that support the weight, making mass production inexpensive and easy, and no need for boilers or nuclear reactors. Departure A horizontal axis 1h through-hole for driving the machine 1, the generator 1 is driven plurally outside the turbine outer box 77a, and the multistage saddle-type all blade hydrogravity turbine 8P is driven alternately in the rotational direction, and the gravitational acceleration unit The next turbine 8M is driven by 1g acceleration, and the horizontal axis is alternately driven for 1h one after another, making the structure simple and inexpensive electric products infinite and electric driving infinite, the world's best energy conservation cycle combined engine power generation and combination Turn to method power generation.

The vertical all-blade hydrogravity turbine 8P power generation consists of six parts, one set with two types of cylindrical annular assemblies 9A, and one unit with 100-200 sets vertically installed in the highest building 828m in the turbine outer box 77a. The thrust bearings 80a of the inner shaft device 60A and the outer shaft device 60B are provided with bearings 80 for the purpose of using a magnetic bearing load 0, and the contra-rotating magnetic device 85 is configured with a horizontal shaft 1h gear, and the cylindrical inner rotor blade group 60C cylinder The outer rotor blade group 60D is driven in a counter-rotating manner by rotating alternately for each turbine, and the vibration and noise are minimized by the turbine drive canceling the resonance. The injection speed by the specific material accelerator 6W + the gravitational acceleration in vacuum = Mach 30 target As the injection speed, water 3E injection is performed, and the gravity acceleration acceleration effect in vacuum is maximized. The cylinder inner blade group 60C is injected into the cylindrical outer blade group 60D, and each is driven by a 1h horizontal inversion drive power generation to generate a Mach. Maintaining the target speed and driving the next turbine to effectively use the head to make a vertical all-blade water gravity turbine 8P power generation. Water 3E injection with 6W equipped for each set, specific material accelerator 6W equipped with distilled water production amount and cooling amount of friction heat vaporized water, water cooled and 30mmHg etc. with air extractor 51 Easily over the existing power generation maximum vacuum degree, 100 to 200 sets are used for the drop 828m, and compared to the final stage of the existing steam turbine power generation, 100 units are stacked as 100% as Mach 1-speed steam of 43,000 times the volume of vacuum 30mmHg water Compared with the turbine 8P Mach 1 power generation amount, the power generation of 1/1000 volume of water is 43 × 100 = 4300 times the amount of water power generation by Mach 1 speed injection, and the power generation of astronomical magnification that requires experimentation Various energy storage cycle combined engine fuel costs become zero.

  The most important configuration of the cylindrical inner assembly 9A of the cylindrical inner rotor blade group 60C in FIG. 1 is super water-repellent and the lowest friction loss is the most important. The water-repellent coating 3b is easy and has a structure that facilitates the operation, and the inner shaft device 60A and the outer shaft device 60B in FIG. 1 each have the cylindrical annular assembly 9A, and the outer shaft device 60B and the cylindrical annular assembly 9A are connected to the inlet fixed outer blade. 60E annular fitting assembly fixing constitutes the inlet moving blade group of the cylindrical outer moving blade group 60D, and the inner shaft device 60A and the cylindrical annular assembly 9A are connected to the inlet fixed inner blade 60F annular fitting assembly fixing, and the cylindrical inner moving blade group. A 60C inlet blade group is formed, and the outer shaft device 60B and the cylindrical annular assembly 9A are formed by an outer annular blade 60G annular fitting assembly to form an intermediate blade group of the cylindrical outer blade group 60D, and the inner shaft device 60A. And cylindrical annular assembly 9A The 60H annular fitting assembly constitutes an intermediate moving blade group of the cylindrical inner moving blade group 60C, and the outer shaft device 60B and the cylindrical annular assembly 9A are formed by the outer annular blade 60G annular fitting assembly to form the cylindrical outer moving blade group 60D. The second intermediate blade group is configured, and the inner shaft device 60A and the cylindrical annular assembly 9A are configured as an outlet fixed inner blade 60K annular fitting assembly and fixed to form an outlet blade group of the cylindrical inner blade group 60C, and the outer shaft The device 60B and the cylindrical annular assembly 9A are configured to fix the outlet fixed outer blade 60J in an annular fitting assembly, thereby forming the outlet blade group of the cylindrical outer blade group 60D, and more than 100 sets of six types of cylindrical blade groups 60 are fully automatic. Manufacture by manufacturing, etc. As one unit manufacturing etc., it is extremely easy to make fully automatic processing, easy assembly, simple structure, no need of boilers and nuclear reactors, etc., making the manufacturing cost extremely low, and having the best operating profit rate in the world with no fuel cost, etc.竪 All-blade water gravity turbine 8P extremely inexpensive To power.

Heat production of the solar heater 21 in FIG. 3 is a vertical all blade water gravity turbine 8P fuel cost 0 power generation extremely cheap electric drive, cheap electricity + liquid air cold heat + superheated steam temperature supply equipment 3D The solar heater 21 has a buoyancy on the water surface or a circular railroad on a flat surface, and the solar heater 21 is used as a floating device or a land device for maintaining and rotating sunlight at a right angle from east to west. A rotation support part 4f is provided, and a gear unit 4d and a roller 4e are provided. It is a device that controls the rotation of sunlight in two directions at right angles to maximize the air temperature in the heat absorption tube 4H, collects sunlight with the maximum amount of heat in a straight line by the rectangular long lens 2d, and absorbs heat near the focal length. Inside pipe 4H The temperature of the air passage 28A air 28a is maximized, the temperature of the external air passage 28A air 28a rises, and the existing lens cross section is linearly extended as a rectangular long lens 2d, so that all the lens materials can be used. The heat insulating material 2c is surrounded by a cylindrical rotating part 77G or the like to form a long cylinder such as a cylinder, the long long lens 2d is a joint 80A + clamp 80B, and the sealed upper part is a 4H external air passage 28A. 1 to multi-stage heat pump 1G is suction-compressed, theoretical gas compressor 3T and the like is heat pump 1G at 800 to 1200 ° C. multiple times, and 1 to multi-stage compression heat recovery unit 2C repeats heat recovery for each compression, Liquid air 28a cold heat is stored in the liquid oxygen chamber 5K + liquid nitrogen chamber 5L, and 24-400 MPa superheated steam 50 warm heat around 400 ° C. is divided and stored in the high-pressure high-temperature steam chamber 5N. The liquid air cold + superheated steam heat supply equipment 3D using various applications, and the electric drive flourish and battery driven prime, to various thermal utilization prime and various cold use PRIME electrical product.

The theoretical gas compressor 3T of FIG. 4 is equipped with a repulsive permanent magnet 9B attracting permanent magnet 9C compressed air part 9D vacuum part 9E water injection part 6F aiming at super-large size, ultra-high speed rotation, and compression ratio greatly increased, and uses magnetic force + air pressure. With a bearing load approaching zero or using heat of vaporization, the compression ratio of one unit is greatly increased, and Boyle's law gas volume is inversely proportional to the pressure. The best aim is to compress the suction from the large circumferential blade to the central short blade. As a result, the maximum intake air amount is aimed at, and the intake air velocity is aimed at the maximum at the upper compression blade group 8g and the lower compression blade group 8h of all the rotor blades, and the assembly compression blade group 8j facilitates assembly and suction. With the mouth area maximum easy and the compression efficiency best aiming, the vertical rotating blade water gravity turbine 8P fuel cost 0 power generation extremely cheap electric drive, by the double reversal magnetic (gear) device 85 (85Y) of the horizontal shaft 1h gear, Upper compression blade group 8g lower compression The group 8h is rotated in the opposite direction to rotate in the opposite direction, the relative peripheral speed is 3 to 10 times that of the existing axial flow compressor, and the theoretical best gas compressor 3T is used. The heat production is press-fitted into the heat exchanger 2Y, and the heated air of the solar heater 2 is mainly compressed with a heat pump 1G such as a theoretical gas compressor 3T, and 1 to multiple-stage compression heat recovery units 2C for each compression high temperature. Heat recovery, liquid air cold heat + superheated steam temperature divided and stored as electricity + liquid air cold heat + hot water to superheated steam temperature supply equipment 3D, cheap superheated steam is used for rice cooking, methane recovery, greenhouse cultivation, etc. Inexpensive liquid oxygen is used for infinite heating applications, such as driving automobiles, ships and airplanes with a compression work rate of 21/60000 of air compression. Inexpensive liquid nitrogen is used for various purposes such as infinite cooling applications such as ice production. use It is.

The theoretical expansion engine 3Q aiming at oxygen-hydrogen increase combustion in the ultra-high pressure extreme combustion of FIG. 5 is equipped with a repulsive permanent magnet 9B attracting permanent magnet 9C compressed air portion 9D vacuum portion 9E aiming at ultra-low cost rotation output such as ultra-large size and ultra-high speed rotation. , Use of magnetic force + air pressure to make bearing load close to 0, vertical type blade dynamic gravity turbine 8P fuel cost 0 power generation extremely cheap electricity production from electricity + liquid air cold heat + hot water to superheated steam temperature supply equipment 3D, liquid By receiving oxygen 5K + electricity + high temperature water and compressing liquid oxygen 5K, the compression volume work rate is 21/60000 volume compression work rate of air compression, and liquid oxygen 5K + liquid fuel 1c + high temperature water 52a is 24 to 200 MPa. Compressed to ultra-high pressure, open liquid oxygen control valve 5T + liquid fuel control valve 1K + water control valve 5Q, theoretical combustion chamber 4Q inner wall fuel heating pipe 1L hot water heating pipe 5H oxygen heating pipe 5F Heat up each time, open the superheated steam control valve 25 + oxygen control valve 24D + fuel control valve 25b (not shown), burn near 3000 ° C near the super high pressure fuel oxygen center, and part of the superheated steam 50 near the center The superheated steam 50 is heated to an optimum temperature on the inner wall, and the superheated steam 50 is heated to the optimum temperature, and the superheated steam 50 is injected into the superheated steam injection nozzle 6A, and the combustion gas injection nozzle 6Y and the combustion gas 49 are sucked and compressed. The compressed air portion 9D of the air passage 5b of the air injection nozzle 5 is sucked and injected to drive the theoretical expansion engine 3Q that greatly increases the fuel injection combustion combustion amount from the fuel injection nozzle 6X of the fuel pipe 25c and increases the fuel combustion amount. The combustion gas 49 is changed to a high-pressure high-temperature combustion gas 49 and injected from the center in a circumferential direction of 380 degrees, and the upper expansion blade group 8d and the lower expansion blade group 8e are optimally injected. And drive the volume of Boyle's law gas as the best theoretical expansion engine 3Q theory which is inversely proportional to the pressure, the theoretical expansion engine 3Q which injects the turbine outer casing 77a assembled turbine blade group 8f.

The rocket combustion + jet combustion drive of the oxygen coalescence water injection unit 88L aiming at oxygen-hydrogen increase combustion in the ultra-high pressure extreme combustion of FIG. 6 is a vertical all blade water gravity turbine 8P fuel cost 0 power generation + Liquid air cold heat + High temperature water-Superheated steam temperature supply equipment 3D receives liquid oxygen 5K + electricity + high temperature water and compresses liquid oxygen 5K, thereby compressing the compression volume work rate to 21/60000 volume compression of air compression Compress the liquid oxygen 5K + liquid fuel 1c + high temperature water 52a to ultrahigh pressure such as 24-200 MPa, open the liquid oxygen control valve 5T + liquid fuel control valve 1K + water control valve 5Q, and heat the fuel in the theoretical combustion chamber 4Q inner wall Tube 1L + high temperature water heating tube 5H + oxygen heating tube 5F is heated to the optimum temperature, superheated steam control valve 25 + oxygen control valve 24D + fuel control valve 25b is opened, and super high pressure fuel oxygen center High-pressure high-temperature superheated steam 50 is heated by multiple combustion at 3000 ° C. or more, and a part of the superheated steam 50 is aimed at increased combustion by suction pyrolysis electrolysis oxygen-hydrogen hydrogen near the center. Ultra-high pressure high-temperature rocket combustion injection with suction of combustion gas 49, fuel injection nozzle 6X multiple fuel injection jet combustion into air suction flow, ultra-high pressure high-temperature rocket combustion + jet combustion 1 to multiple times, the most ultra-high pressure is the easiest Various superheated steam 50 is set to the maximum injection speed by core superheat injection, forward air 28a is sucked and injected, and forward water 52a is sucked and injected to form an oxygen combined water injection unit 88L. To the way.

The rocket combustion + jet combustion drive of the oxygen coalescence air injection unit 88B aiming at oxygen-hydrogen increase combustion in the ultrahigh-pressure limit combustion of FIG. 7 is a vertical all blade water gravity turbine 8P fuel cost 0 power generation + Liquid air cold heat + High temperature water-Superheated steam temperature supply equipment 3D receives liquid oxygen 5K + electricity + high temperature water and compresses liquid oxygen 5K, thereby compressing the compression volume work rate to 21/60000 volume compression of air compression Compress the liquid oxygen 5K + liquid fuel 1c + high temperature water 52a to ultrahigh pressure such as 24-200 MPa, open the liquid oxygen control valve 5T + liquid fuel control valve 1K + water control valve 5Q, and heat the fuel in the theoretical combustion chamber 4Q inner wall Tube 1L + high temperature water heating tube 5H + oxygen heating tube 5F is heated to the optimum temperature, superheated steam control valve 25 + oxygen control valve 24D + fuel control valve 25b is opened, and super high pressure fuel oxygen center The high-pressure high-temperature superheated steam 50 is heated by multiple combustion in the vicinity of 3000 ° C or more, and a part of the superheated steam 50 is aimed at the combustion by suction pyrolysis electrolysis oxygen hydrogen hydrogen increase near the center, and the superheated steam injection nozzle 6A aimed at the inner wall protection 200 MPa The combustion gas 49 is sucked and injected into the super high pressure high temperature rocket combustion injection, the fuel injection nozzle 6X multiple fuel injection jet combustion into the air suction flow, the ultra high pressure high temperature rocket combustion + jet combustion one or more times, The easy superheated steam 50 is set to the maximum injection speed by core superheat injection, and the forward air 28a is sucked and injected into the oxygen combined air injection unit 88B to form various energy storage cycle combined engines and combined methods.

The theoretical combustion chamber 4Q theoretical expansion engine 3Q drive of the theoretical expansion engine automobile 4L aiming at hydrogen + oxygen increase combustion in the ultra high pressure limit combustion of FIG. 8 is a vertical all blade hydrogravity turbine 8P fuel cost 0 power generation extremely cheap electric production The liquid oxygen 5K + electricity + high temperature water is received from the electricity + liquid air cold heat + high temperature water to superheated steam temperature supply facility 3D, the high temperature water 52a is compressed to 200 MPa by the water pump 4c, and the liquid fuel 1c is liquid fuel. By compressing with pump 4a and compressing liquid oxygen 5K with liquid oxygen pump 4b, the compression volume work rate is 21/60000 volume compression work rate of air compression, and the liquid oxygen control valve 5T is opened to theoretically burn liquid oxygen 5K. Supply overheat to the inner wall of the chamber 4Q, overheat the water control valve 5Q open high temperature water 52a to the inner wall of the theoretical combustion chamber 4Q, and oversupply the liquid fuel control valve 1K open liquid fuel 1c to the inner wall of the theoretical combustion chamber 4Q Then, superheat +200 MPa high-temperature superheated steam 50 is produced at the optimum super-high pressure temperature, the superheated steam control valve 25 + oxygen control valve 24 D + fuel control valve 25 b is opened, and the combustion near the oxygen fuel super-high pressure center is made to be a plurality of combustions of 3000 ° C. or more, The inner peripheral high-temperature water heating pipe 5H and the like are heated, and a part of the superheated steam 50 is aimed to increase the suction pyrolysis / electrolysis / oxygen / hydrogen hydrogen combustion in the combustion section near the center, and the liquid oxygen 5K + liquid fuel 1c + high temperature on the inner wall of the theoretical combustion chamber 4Q The water 52a is heated, and the superheated steam 50, the fuel, oxygen, and the inner wall of the optimum temperature, and the inner wall is protected and super high pressure / high temperature combustion, and the high pressure / high temperature combustion gas control valve 5a (not shown) is driven to open the theoretical expansion engine 3Q, Drive the generator 1 and store it in the storage battery 1A, drive the storage battery drive wheel 4J, aim CO2 exhaust 1/10 fuel cost 1/10 operating profit rate 10 times that of existing cars, theoretical expansion engine automobile 4L To, to various energy saving cycle combined institutions and coalescence method.

Fig. 9 The theoretical expansion engine 3Q drive of the theoretical combustion chamber 4Q, aiming to increase oxygen hydrogen in the ultra-high pressure extreme combustion of the oxygen coalescence screw ship 39Q, is a vertical all-blade water gravity turbine 8P fuel cost 0 power generation extremely cheap electricity production , By receiving liquid oxygen 5K + electricity + high temperature water from the electricity + liquid air cold heat + high temperature water to superheated steam temperature supply facility 3D and liquid compressing the liquid oxygen 5K, the compression volume work rate is reduced to 21 / The liquid oxygen control valve 5T + liquid fuel control is performed by compressing the liquid oxygen 5K + liquid fuel 1c + high temperature water 52a to an ultrahigh pressure such as 24-200 MPa by the liquid fuel pump 4a + liquid oxygen pump 4b + water pump 4c. Open the valve 1K + water control valve 5Q, heat to the optimum temperature on the inner wall of the theoretical combustion chamber 4Q, open the superheated steam control valve 25 + oxygen control valve 24D + fuel control valve 25b In the vicinity of the super high pressure fuel oxygen center, combustion is performed at a temperature of 3000 ° C. or more, and a part of the superheated steam 50 is sucked into the near center combustion, aiming at pyrolysis electrolysis oxygen hydrogen increase combustion, and liquid oxygen 5K + on the inner wall of the theoretical combustion chamber 4Q The liquid fuel 1c + high temperature water 52a is heated to produce superheated steam 50, fuel, oxygen, inner wall protection combustion or super high pressure / high temperature combustion at the optimum temperature, and the high pressure / high temperature combustion gas control valve 5a is opened. Selectable, drive the screw to drive the oxygen coalescence screw ship 39Q, CO2 exhaust 1/10 fuel cost 1/10 operating profit rate 10 times the target of the existing ship, make the oxygen coalescence screw ship 39Q, various energy conservation cycle coalescence Institutions and coalescing methods.

FIG. 10 Oxygen combined water injection unit 88L + theoretical expansion engine 3Q driving by the theoretical combustion chamber 4Q, aiming at increased combustion of oxygen and hydrogen in the ultra high pressure limit combustion of the oxygen combined screw injection ship 39S, is a vertical type full blade air gravity turbine 8P fuel cost 0 Power generation of extremely cheap electricity, electricity + liquid air cold heat + high temperature water to superheated steam temperature supply equipment 3D receives liquid oxygen 5K + electricity + high temperature water, and the screw drive by the theoretical expansion engine 3Q is 1h on the horizontal axis in FIG. The driving is the same as described in FIG. 9 and the driving is performed as shown in FIG. 9, and the oxygen combustion water injection section 88L is moved to the theoretical combustion chamber 4Q in FIG. 5 as shown in FIG. 6 is provided as a propulsion, and an intake air passage 5b is provided around the leading theoretical combustion chamber 4Q combustion gas injection nozzle 6Y. Type theory combustion chamber 4Q1-Optimal number of chambers according to the application, liquid oxygen 5K compression to 21/60000 volumetric compression work rate of air volumetric compression work rate, combustion gas suction rocket with 200A target superheated steam injection nozzle 6A injection Fuel jet nozzle 6X multiple jet combustion, sucking forward air and sucking and jetting water, sucking and jetting water into large and small vessels, high-speed vessels and ultra-high-speed vessels to be propelled, jet combustion for rocket combustion Oxygen combined water injection part 88L super high pressure mass combustion 100 times output aiming to increase the combustion amount added, 10 times speed aiming injection propulsion of existing ship, same speed CO2 exhaust 1/10 fuel cost 1/10 operating profit Establish an oxygen coalescence water injection unit 88L aiming at 10 times the rate of existing ships, and various energy conservation cycle coalescence engines and coalescence methods.

Fig. 11 Oxygen hydrogen increased combustion by the theoretical combustion chamber 4Q, aiming at increased oxygen hydrogen combustion in the ultra high pressure limit combustion of the oxygen combined injection ship 39R, the vertical combined water blade water gravity turbine 8P fuel cost 0 power generation is extremely inexpensive electricity Liquid oxygen 5K + electricity + high temperature water is received from the electricity + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment 3D, and the theoretical combustion chamber 4Q is provided to the oxygen combined water injection unit 88L as shown in FIG. A streamlined theoretical combustion chamber 4Q1 shown in FIG. 6 is provided, in which the air 28a around the leading theoretical combustion chamber 4Q serves as the intake air passage 5b, and the fuel injection nozzle 6X injects fuel into the intake air or the like to form rocket combustion + jet combustion. Select multiple units according to the application, liquid oxygen 5K compression, air volume compression work rate 21/60000 volume compression work rate, superheated steam injection nozzle 6A injection aiming at 200 MPa , Internal combustion gas suction injection + jet combustion + forward air suction injection + forward water suction injection to make large, small, high-speed and ultra-high-speed vessels propelling injection, jet combustion added to rocket combustion Oxygen combined water injection unit 88L ultra high pressure mass combustion 100 times output with increased combustion amount, wide vertical parallel plate 9Q for oxygen combined injection ship 39R injection propulsion air floating, maximum air floating amount + maximum friction reduction amount Various energy conservation cycles, aiming at 10 times the target injection propulsion of the existing ship, the oxygen speed water injection unit 88L aiming at 10 times the same speed CO2 exhaust 1/10 fuel cost 1/10 operation profit rate of the existing ship Use a coalescence engine and coalescence method.

Fig. 12 Oxygen hydrogen injection in the theoretical combustion chamber 4Q, aiming at increased oxygen hydrogen combustion in the ultra-high pressure extreme combustion of the oxygen combined injection airplane 39T, is driven by a vertical all-blade water gravity turbine 8P fuel cost 0 power generation extremely inexpensive electricity Liquid oxygen 5K + electricity + high temperature water is received from the electricity + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment 3D of manufacture, and the theoretical combustion chamber 4Q is provided in the oxygen combined air injection unit 88B as shown in FIG. Then, the air 28a around the leading theoretical combustion chamber 4Q is used as the intake air passage 5b, and the fuel injection nozzle 6X performs fuel injection combustion on the intake air or the like to form rocket combustion + jet combustion. Is selected according to the application, liquid oxygen 5K compression is set to 21/60000 volume compression work rate of air volume compression work rate, superheated steam injection nozzle 6A jet aimed at 200 MPa In the internal combustion gas suction injection + jet combustion + forward air suction suction injection, propelled by rocket combustion + jet combustion and propelled by rocket combustion, and as a variety of planes that travel to and from space by rocket combustion, combine oxygen The air injection unit 88B aims to produce 100 times the output of ultra high pressure mass combustion, enabling day trips anywhere on the earth, such as making 16 orbits of the earth in a space-use prime day that is close to zero fuel cost. 10 Fuel cost 1/10 Operating profit ratio The target is 10 times that of an existing airplane, and the oxygen coalescence air injection unit 88B is used, and various energy storage cycle coalescence engines and coalescence methods are used.

Fig. 13 Oxygen hydrogen propulsion aiming at increased oxygen hydrogen combustion in the ultra-high pressure extreme combustion of the oxygen combined propeller plane 39U, Fig. 5 Theoretical combustion chamber 4Q theoretical expansion engine 3Q propeller 7A drive is a vertical all blade water gravity turbine 8P fuel cost 0 power generation extremely cheap Receives liquid oxygen 5K + electricity + high temperature water from electricity + liquid air cold heat + hot water to superheated steam temperature heat supply equipment 3D, and aims at 200 MPa by liquid compression, liquid oxygen control valve 5T + liquid fuel control valve 1K + The water control valve 5Q is opened and heated to the optimum temperature by the theoretical combustion chamber 4Q inner wall fuel heating pipe 1L + high temperature water heating pipe 5H + oxygen heating pipe 5F, and the superheated steam 50, fuel and oxygen at the optimum temperature are controlled. The valve 25 + oxygen control valve 24D + fuel control valve 25b is opened and combustion is performed at a temperature of 3000 ° C. or more near the ultrahigh pressure fuel oxygen center, and a part of the superheated steam 50 is sucked near the combustion center. With the aim of deelectrolytic oxygen hydrogen augmentation combustion, protective combustion of the inner wall and ultra high pressure / high temperature combustion, 200 MPa aiming superheated steam 50 is injected with superheated steam injection nozzle 6A, combustion gas injection nozzle 6Y combustion gas 49 is sucked and injected, Compressed intake air passage 5b Compressed air portion 9D of the air injection nozzle 5 sucks and injects air, and the theoretical expansion engine 3Q drive increases the fuel combustion amount by significantly increasing the fuel injection combustion combustion amount from the fuel pipe 25c fuel injection nozzle 6X The combustion gas 49 is driven as a high-pressure and high-temperature combustion gas 49, and the theoretical expansion engine 3Q is driven by 380 degrees of circumferential direction injection from the center, and the propeller 7A drive and the rotor blade 7B drive are driven by the horizontal axis 1h. CO2 exhaust 1/10 fuel cost is targeted to 1/10, and operating profit margin is set to 10 times that of existing airplanes, etc. To injection airplane 39N, to a variety of energy storage cycle combined institutions and coalescence method.

Compared with the existing pumped-storage power generation, the vertical-type full-blade water gravity turbine 8P power generation aiming at a resource price of 0 fuel costs of 0 power generation less than 1/2 of the nuclear power generation will be explained. Gravity acceleration in vacuum is added to water injection speed Mach 3 or higher, and work rate is proportional to speed + proportional to height, so water injection speed Mach 3 or higher + gravity acceleration in vacuum = Mach 30 and so on 100 times speed 1/100 mass vertical water drive + all-blade horizontal axis 1h double reversal drive, maximum power of 9.8m / sec in gravity in vacuum, 200 sets at the world's highest building height of 828m There is a possibility of extremely low-priced power generation with a vertical all-blade water gravity turbine 8P power generation that has a vertical power generation of one unit and the same amount of water generation 200 times that of existing pumped power generation.

In the process of comparing the vertical power blade hydrogravity turbine 8P power generation with the existing thermal power nuclear steam turbine power generation, aiming to reduce the resource price 0 fuel cost 0 power generation cost to less than 1/2 of the nuclear power generation, the atmospheric pressure 100 according to Boyle's law Assuming that the steam velocity of 1700 times the water at 760 ° C. and water is 43000 times the volume of water at the exhaust temperature of 29 ° C. and the vacuum pressure of 30 mm Hg, and assuming that the steam velocity of the existing steam turbine final blade group is the sonic velocity, the inlet high pressure blade group Since the steam velocity is 1 / 100th the speed of sound or less, the work rate is the lowest, so the comparison will be made with the last blade group having the highest work rate. When the water drive volume is 1/43000 volume 29 ° C water drive of the steam 29 ° C volume, the same power generation amount is obtained by driving the 6-stage front and rear blade groups that are double-reversed for 1 h for all the rotor blades. If it is calculated by elementary school science, such as 200 times the amount of power generated by 200 sets of 200 units connected, there is a possibility that extremely low-cost power generation will become an astronomical large amount of power generation.

Vertically moving blade water gravity turbine 8P power generation Extremely inexpensive power generation, as an electric product prime, it receives superheated steam from electricity + liquid air cold heat + superheated steam temperature supply facility 3D, methane hydrate under the seabed or permafrost For food companies, methane recovery, permafrost conversion to pasture grazing conversion, superheated steam injection in oil sands, oil shale, and aging oil collection areas, vaporization recovery liquefaction preservation, etc. There is a possibility of receiving cheap superheated steam for mass production of cheap food products, etc., and using it for agricultural, industrial, industrial or mining industries to make full use of heat.

Vertical type moving blade water gravity turbine 8P power generation Extremely inexpensive power generation, as an electric product prime, electric + liquid air cold heat + superheated steam temperature supply equipment 3D receives liquid oxygen 5K, and is driven by liquid oxygen automobiles and ships Or a plane, etc., and compressing liquid oxygen 5K to 21/60000 volumetric compression work rate of air volumetric compression work rate, driving theoretical expansion engine 3Q, oxygen combined water injection unit 88L and oxygen combined air injection unit 88B However, in the case of automobiles, CO2 emissions and fuel costs may approach 1/10, ships may approach 10 times the speed with the same fuel costs, and planes will have a space arrival cost of 1 / 500,000, etc. There is a possibility that it will become a major revolution in the use of cold energy, such as making a day trip anywhere on the earth as a prime use.

0: Various energy storage cycle coalesced engine (various heat energy is compressed and recovered by heat pump as air temperature, divided into liquid air cold heat + superheated steam heat, and gravitational energy is increased storage spray accelerated by acceleration of gravity in vacuum Various energy coalescence engine coalescence means used for conversion to generated power) 0: Various energy storage cycle coalescence engine and coalescence method (various thermal energy is heated by solar heat or geothermal heat, etc., compressed air is recovered by a heat pump as air temperature, liquid air cooling + Divided and stored in superheated steam temperature ・ Used with a heat retaining device when using liquid metal below 500 ℃ ・ Shock energy is set to turbine blades and small-diameter metal balls, and silicon resin coating or fluororesin coating is provided to extend the working time Use / gravity energy is ascended by the ascending device, stored and sprayed, accelerated by gravitational acceleration in vacuum, and converted into energy using generated power Combined engine and various energy combining means) 1: generator, 1A: storage battery, 1B: pressure engine (oxygen pressure gear engine, oxygen pressure reciprocating engine, water pressure gear engine, water pressure reciprocating engine, etc.) 1C: alcohol, 1D: fuel injection pump, 1F: condensate pump, 1G: 1 to multistage heat pump (heat pump with heat energy as air temperature (various air (Compressor) Multiple times compression 2C 2X2Y2Z 2X2Y2Z Multiple times heat recovery heat 50 + Cold 28a) 1K: Liquid fuel control valve, 1L: Fuel heating pipe, 1Y: Multiple stage combustion chamber (Separate liquid oxygen and liquid nitrogen Compressed 24 to 200 MPa Combustion gas and nitrogen gas are manufactured separately, and 1Y is subjected to water vapor heating inside and outside the combustion gas injection, fuel injection combustion, and injected or exhausted) 1b: Fuel (liquid 1b: Fuel pipe (provided so that the fuel injection temperature becomes the optimum temperature) 1c: Liquid fuel, 1d: Mercury, 1g: Gravity acceleration unit, 1h: Horizontal axis (outer shaft device and inner side) 2) Sunlight heater (collects sunlight in a straight line with a long lens and heats the high-temperature portion forming intake air) 2a: Speeds up the natural phenomenon (change in air is almost zero) When the leftovers move to a nearby river, a huge amount of microorganisms that approaches zero overnight will be used to increase food for humans. Equipment that increases the supply of nutrients such as nitrogen, oxygen, and CO2 and increases foods such as fish and kombu. 2a: Speeds up natural phenomena (in ships, the supply of nutrients such as nitrogen, oxygen, and CO2 into the sea makes it possible to digest microorganisms. Planting aiming tens of thousands times the forest 2b: Low water resistance (lowly sprays air + combustion gas + superheated steam to the bottom of the ship to minimize water resistance) 2c : Insulating material, 2d: Long lens (Convex lens cross section linearly extended rectangle, multiple lenses are used to aim the maximum focal length shortest lens width) 2e: Water surface, 2g: Specific material acceleration direction, 2A: Heat-resistant material, 2B: Heat Absorbent, 2C: 1 to multi-stage compression heat recovery device (heat energy is air temperature, compression multiple times with heat pump, heat recovery is used multiple times with various heat exchangers such as 2C2X2Y2Z of 2C, and the rest is heated 50 + liquid cold 28a 2E: Specific critical substances (including alloys, platinum balls, gold balls, tungsten alloy powder sintered balls, silver balls, copper balls, tin balls, lead balls, zinc balls, aluminum balls, indium, cadmium, gallium, and tari 2E: Specific critical material (Manufacturing method reduces the impact energy as the diameter decreases. For example, molten steel is injected into the air to produce ultra-small diameter steel balls by high-speed collision pulverization air cooling water cooling) 2E : Specific critical materials (coated platinum alloy balls, coated gold alloy balls, coated tungsten alloy powder sintered balls, coated silver alloy balls, coated bismuth alloy balls, coated copper alloy balls, coated tin alloy balls with silicon resin coating or silicon resin coating)・ Coated lead alloy sphere ・ Coated zinc alloy sphere ・ Coated aluminum alloy sphere 2F: Specific critical substance elevating device (Gravity energy is increased and stored) 2H: Chilled seawater mixer (mixed cold water into seawater and overheated in the process of speeding up natural phenomenon) 2X: Air heat exchanger (the air is compressed with a heat pump at a high temperature, aiming at infinite increase in heat recovery compressed air mass or infinite increase in pressure) 2Y: Compressed air heat exchanger ( 2Z: Specific critical material heat exchanger (used for temperature control of liquid metal below 500 degrees) 3a: Water repellent plating, 3A: Water repellent coating, 3D: Electricity + liquid air cold heat + superheated steam heat supply equipment (cooled heat + heat production with gravity power generation electricity, supply liquid oxygen and liquid nitrogen drive car, ship and airplane, supply with superheated steam, recover methane injected into methane hydrate, etc. 3E: Specific critical substances (specific critical substances that are liquid at room temperature, such as mercury and water) 3E: Specific critical substances (low-melting-point liquids that are stable in liquids up to 500 degrees C) 3F: Oxygen pressure reciprocating engine (liquid oxygen, liquid nitrogen, and fuel are used as injection combustion 24-200 MPa combustion gas, and fuel injection multistage combustion is driven during expansion to drive a multistage oxygen pressure reciprocating engine) 3G: Theoretical combustion tooth Engine (liquid oxygen + liquid fuel + water is compressed and heated for injection combustion) 3H: reciprocating piston, 3J: theoretical combustion reciprocating engine (liquid oxygen + liquid fuel + water is compressed and heated for injection combustion) 3K: external gear 3L: multistage combustion chamber, 3M: steam pressure reciprocating engine (multistage oxygen pressure reciprocating engine heats water and steam in multiple stages to drive the multistage steam pressure reciprocating engine) 3N: steam pressure gear engine (multistage oxygen pressure gear engine) 3P: Theoretical expansion engine (the volume of gas is inversely proportional to the pressure, aiming at the best engine + oxygen-hydrogen-enhanced combustion) 3Q: Theoretical expansion engine (Boiled) 3R: Theoretical gas turbine (theoretical best gas turbine whose gas volume is inversely proportional to the pressure) 3S: Theoretical steam turbine (gas Theoretical best steam turbine whose volume is inversely proportional to pressure 3T: Theoretical gas compressor (Theoretical best gas compressor whose gas volume is inversely proportional to pressure) 3U: Theoretical turbine, 3V: Pump engine (existing various pumps with the engine) Use) 3X: Compressor engine (uses various existing compressors in the engine) 3Y: Counter-rotating engine (engine whose gas volume is inversely proportional to pressure) 3Z: Oxygen pressure gear engine (liquid oxygen, liquid nitrogen and fuel injection) 3a: water-repellent plating, 3b: water-repellent coating, 4F: combustion gas reciprocating engine, 4H: Heat absorption tube (long-lens 2d gathers sunlight in a heat absorption tube in a straight line, and heats the air temperature inside the tube to the maximum to increase the outside air temperature) 4J: Storage battery drive wheel 4K: Theoretical expansion engine vehicle, 4L: Theoretical expansion engine vehicle, 4Q: Theoretical combustion chamber (targeted for ultra-high pressure theoretical combustion) 4W: Theoretical compression chamber, 4Y: Theoretical combustion chamber (the high temperature combustion in water vapor and the heat of water 4Z: Combustion gas gear engine, 4X: Turbine blade cross section (enlarged cross-sectional surface area) 4a: Liquid fuel pump, 4b: Liquid oxygen pump, 4c: Water pump, 4d: Gear device, 4e: roller, 4f: rotation support, 5: air injection nozzle, 5a: high-pressure high-temperature combustion gas control valve, 5b: compressed intake air passage, 5d: combustion flow inner wall, 5e: ultra-high pressure oxygen, 5A: supply Air valve, 5B: Cooling fin, 5C: Exhaust chamber 5D: Exhaust valve 5E: Air supply chamber 5F: Oxygen heating tube, 5G: Steam heating tube, 5H: High temperature water heating tube, 5K: Liquid oxygen, 5K: Liquid oxygen chamber , 5 : Liquid nitrogen, 5L: liquid nitrogen chamber, 5M: high pressure high temperature combustion gas, 5M: high pressure high temperature combustion gas chamber, 5N: high pressure high temperature steam chamber, 5N: high pressure high temperature steam, 5P: steam control valve, 5Q: water control valve, 5R: Superheated steam control valve, 5S: Compressed air heating pipe, 5T: Liquid oxygen control valve, 6: Final compression blade, 6A: Superheated steam injection nozzle, 6B: Compressed air injection nozzle, 6C: Combustion gas steam nozzle, 6E: Specific material injection nozzle, 6F: Water injection nozzle, 6G: Stator blade, 6H: Drain pipe, 6L: Oxygen injection nozzle, 6W: Specific material acceleration machine (Liquid material material 3E pressure and specific gravity difference 6X: Fuel injection nozzle, 6X: Afterburner (combustion with the intake air flow and the fuel injection cold heat 28a combustion flow 6Y, and the combustion rises by increasing the fuel combustion amount) 6Y: Combustion 6Z: Steam injection nozzle, 7A: Propeller, 7B: Rotating blade, 7C: Screw, 8c: Turbine blade (inner and outer rotor blade groups are respectively connected to the cylindrical part of the inner and outer shaft devices) 8d: Upper expansion blade group, 8e: Lower expansion blade group, 8f: Assembly turbine blade group, 8g: Upper compression blade group, 8h: Lower compression blade group 8H: Assembly compressor blade group, 8H: Vertical type all blade turbine (Equipment for all large blades rotating in opposite directions to each other as a small, large output stage, annular same diameter, approximately the same shape, approximately the same length screw assembly 9) 8H: Vertical type moving blade turbine (selection of cemented carbide, silicon resin coating or fluororesin coated turbine blade) 8H: Vertical type moving blade water gravity turbine (existing steam turbine is Damping with a stationary blade Since the force approaches 0, all moving blades are essential, and the work rate is 1 / 360,000, which is as small as that of platinum balls. + Compression heat recovery with a compression heat recovery unit, divided and stored in warm heat + cold storage turbine drive + used for various purposes) 8H: Vertical type full-blade water gravity turbine (because of hot drive + cold drive, the head of use is limited) 8K: Vertical type moving blade water gravity turbine (water gravity turbine in which the rotation direction of the outer shaft device and the inner shaft device is alternated by the horizontal axis 1h) 8L: Critical material gravity relative to the vertical type moving blade Turbine (specific gravity material gravity turbine in which the rotation direction of the outer shaft device and the inner shaft device is alternated by the horizontal shaft 1h) 8M: vertical all blade water gravity turbine (6 types of cylindrical turbine blade group fitting assembly + magnetic utilization) 8N: ０ Type total blade ratio material gravity turbine (6 types of cylindrical turbine blade group fitting assembly + magnetic utilization bearing load approaching 0) 8R: horizontal type full blade water gravity turbine (cylindrical turbine blade group series opposed synchronous rotation + 8S: Horizontal type full blade ratio material gravity turbine (Cylinder turbine blade group series opposed synchronous rotation + Magnetic type bearing load close to 0) 8P: Vertical type full blade hydrogravity turbine ( 6 types of cylindrical turbine blade group fitting assembly + magnetic utilization bearing load 0 approach + super high speed outer peripheral speed) 8Q: vertical type full blade ratio material gravity turbine (6 types of cylindrical turbine blade group fitting assembly) + Turn the magnetic bearing load to 0 and make it an ultra-high speed peripheral speed) 8T: Horizontal full blade hydrogravity turbine (cylindrical turbine blade group series counter-synchronous rotation + approach to magnetic bearing load 0 approach + make the super high speed outer speed) 8U: Horizontal full blade Gravity material gravity turbine (cylindrical turbine blade group serially opposed synchronous rotation + magnetic bearing load approach 0 + super high speed outer peripheral speed) 9: Wear resistant annular assembly (only the critical material flow path including 8c is annularly manufactured with cemented carbide 9A: Cylindrical ring assembly (6 types of wear-resistant cylindrical ring assembly blades make the structure simple, few parts, fully automatic processing, easy assembly, light weight, etc.) 9A: Cylindrical annular assembly (inner fixed outer blade 60E + outer annular blade 60G + outlet fixed outer blade 60J is fitted to form a cylindrical outer blade group 60D, and inlet fixed inner blade 60F + inner annular blade 60H + outlet fixed inner blade 60K is fitted. 9B: Repulsive permanent magnet, 9C: Suction permanent magnet, 9D: Compressed air part, 9E: Vacuum part, 9Q: Vertical parallel plate (vertical for guiding the blast air to the storage stern) flat 10): hull, 10A: cabin, 10b: cockpit, 10c: control room, 10d: cabin, 10e: cargo compartment, 11D: gas cooling room, 16B: vertical axis, 21: solar heater ( 24: Combustion gas control valve, 24A: Compressed air control valve, 24B: Liquid oxygen control valve, 24C: Liquid nitrogen control valve, 24D: Oxygen control valve 24E: Nitrogen control valve, 25: Superheated steam control valve, 25b: Fuel control valve, 25c: Fuel pipe, 28a: Air, 28a: Cold heat (Compression air heat amount is compressed by heating pump 50a with superheated steam 50 heat + Compressed air 28a containing liquid oxygen or liquid nitrogen 28a: Divided and stored in cold heat 28b: Compressed air calorie 28A: Intake air path 28B: Air path inlet 38
: Rotation guide, 38a: flight trunk, 38b: flight wing, 38c: flight tail, 38d: vertical wing, 38e: wing leading edge, 38g: surface wing, 38h: levitation boat, 38B: air suction jet ship (80S80T80Y80Z 38C: Water suction jet ship (80U80X equipped) 39A: Solar thermal gravity plane, 39B: Solar thermal gravity rotating plane, 39C: Solar thermal gravity helicopter, 39D: Screw ship, 39G: Solar thermal gravity flight ship, 39H: Oxygen combined screw ship, 39J: oxygen coalescence injection ship, 39K: oxygen coalescence screw injection ship, 39L: oxygen coalescence injection airplane, 39M: oxygen coalescence propeller airplane, 39N: oxygen coalescence propeller injection airplane, 39P: oxygen coalescence rotor wing airplane, 39Q: oxygen coalescence screw Ship, 39R: oxygen coalescence-injected ship, 39 : Oxygen coalescence screw injection ship, 39T: Oxygen coalescence jet plane, 39U: Oxygen coalescence propeller plane, 40A: Rudder, 49: Combustion gas, 50: Superheated steam, 50: Superheated steam chamber, 50: Thermal heat (heat pump air 28a) 50A: water vapor, 50a: superheated steam injection pipe, 51: air extractor, 51: confluence extractor (extractor for joining) 51A: Air extraction chamber 52a: High temperature water 52a: Deep ocean water 52b: High temperature water 52d: Hot water (changed from 50) 52e: Cold heat (changed from 28a) 55B: Transmission, 60A: Inner shaft device (turbine) Blade equipped device) 60B: Outer shaft device (turbine blade equipped device) 60C: Cylindrical inner blade group (including wear-resistant cylindrical annular assembly fixed blade group) 60D: Cylindrical outer blade group (Wear resistant cylindrical annular assembly fixed blade group including fully automatic machining easy assembly) 60E: Entrance fixed outer blade (Outer blade group assembled into annular assembly) 60F: Inlet fixed inner blade (inlet blade for annular assembly fixing inner blade group) 60G: Outer annular blade (intermediate blade for annular assembly of outer blade group) 60H: Inner annular blade (inner blade) 60J: Outlet fixed outer blade (exit blade for annular assembly fixing of outer rotor blade group) 60K: Outlet fixed inner blade (exit blade for annular assembly fixing of inner rotor blade group) 76: Gear device 77B: Semi-cylindrical outer box, 77F: Injection section outer box, 77G: Cylindrical rotating part, 77a: Turbine outer box, 80: Bearing (including magnetic bearing + air bearing) 80a: Thrust Bearing (including magnetic bearing + air bearing) 80A: Hand, 80B: Fastener, 80Y: Liquid air suction water jet (High pressure high temperature combustion gas 5M High pressure high temperature steam chamber 5N is received and fuel injected and combusted multiple times to 5M, and 5N multiple times from inner circumference and inner circumference outer circumference 80Z: Liquid air suction water jet (receives high pressure high temperature combustion gas 5M high pressure high temperature steam chamber 5N and injects and burns fuel multiple times to 5M to generate 5N 84: Counter-rotating magnetic friction device (injecting by heating multiple times from the inner and outer peripheries, injecting fuel into the air suction flow at several locations, injecting and injecting air, and sucking and injecting water) 84Y: Counter-rotating gear device (device that counter-rotates with existing technology) 85: Counter-rotating magnetic device (gear using magnet) From height to contactless 85Y: Counter-rotating gear device (mutually reverse rotation with the existing horizontal shaft 1h gear) 88A: Oxygen coalescence air injection unit (coalescence with rocket combustion + jet combustion + steam injection, etc.) 88B: Oxygen combined air injection unit (ultra-high pressure rocket combustion + jet combustion + superheated steam injection suction) 88K: Oxygen combined water injection unit (rocket injection + jet combustion + steam injection and combined injection) 88L: Oxygen combined water injection (Super high pressure rocket combustion + jet combustion + superheated steam injection suction) 95a: combustion gas reservoir, 95b: compressed air reservoir, 95c: superheated steam reservoir, 103: cold energy recovery device,

Claims (377)

  A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 20 sets of power   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 21 to 40 sets of power.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 41-60 sets of power.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 61 to 80 sets of power.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 81 to 100 sets of power.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 101 to 120 sets of power.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) 121-140 sets of various energy storage cycle coalescence engines and coalescence methods.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) 141 to 160 sets of various energy storage cycle coalescence engines and coalescence methods.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) 161 to 180 sets of various energy storage cycle coalescing engines and coalescence methods.   A vertical all-blade hydrogravity turbine consisting of 6 types of blades (9A) + magnetic bearing load approaching 0 + ultra-high speed circumferential speed, each of which is a wear-resistant super water-repellent plating (3a). 8P) Various energy storage cycle coalescence engines and coalescence methods for generating 181 to 200 sets of power.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for generating 1 to 20 sets of vertical type moving blade water gravity turbines (8P) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engines and coalescence methods for generating power by generating 21 to 40 sets of vertical-type full-blade water gravity turbines (8P) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engine and coalescence method for generating 41-60 sets of vertical-type all-blade water gravity turbine (8P) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for generating a power generation of 80 to 80 sets of vertical all blade hydrogravity turbine (8P) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engine and coalescence method for generating a vertical all-blade water gravity turbine (8P) 81 to 100 power generating sets driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating a vertical all-blade hydrogravity turbine (8P) 101-120 power generation driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for generating a power generation of vertical-type all-blade water gravity turbine (8P) 121-140 sets driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engines and coalescence methods for generating power by generating a vertical all-blade hydrogravity turbine (8P) 141 to 160 sets to be driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engine and coalescence method for generating a set of vertical-type all-blade water gravity turbine (8P) 161-180 sets driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating a vertical all-blade water gravity turbine (8P) 181 to 200 sets of electric power to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating 1-20 sets of vertical full-blade water gravity turbines (8P) to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescing engines and coalescence methods for generating vertical 40-wheel hydrogravity turbine (8P) 21-40 power sets to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engine and coalescence method for generating 41 to 60 sets of vertical-type full-blade water gravity turbine (8P) to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engine and coalescence method for generating a vertical all blade water gravity turbine (8P) 61-80 sets of power generation to drive.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engine and coalescence method for generating a vertical all-blade water gravity turbine (8P) 81 to 100 sets of power generation to drive.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engine and coalescence method for generating a vertical all-blade water gravity turbine (8P) 101-120 power generation to drive.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescing engines and coalescence methods for generating vertical power blade water gravity turbine (8P) 121-140 sets to drive.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescing engine and coalescence method for generating a power generator of a vertical all-blade water gravity turbine (8P) 141 to 160 sets to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for driving a vertical all-blade water gravity turbine (8P) 161-180 sets to drive.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engine and coalescence method for generating a vertical all-blade water gravity turbine (8P) 181 to 200 sets of electric power to be driven.   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 20 sets of vertical-type full-blade water gravity turbines (8P) driven by a drive or generator (1).   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescing engines and coalescence methods for generating a power generator and a generator (1) vertical full-wing blade water gravity turbine (8P) 21 to 40 sets.   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engines and coalescence methods for generating 41 to 60 sets of vertical type moving blade water gravity turbine (8P) driven by a drive or generator (1).   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engine and coalescence method for generating power from 61 to 80 sets of vertical type moving blade water gravity turbine (8P) driven by a drive or generator (1).   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engines and coalescence methods for generating a power generation of a vertical type moving blade water gravity turbine (8P) 81 to 100 sets driven and generator (1).   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engines and coalescence methods for generating power generation of a vertical type moving blade water gravity turbine (8P) 101-120 driven by a drive or generator (1).   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engine and coalescence method for generating a power generator and a generator (1) vertical all blade water gravity turbine (8P) 121-140 sets.   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engine and coalescence method for generating a power generator and a generator (1) vertical all blade water gravity turbine (8P) 141-160 sets.   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engine and coalescence method for generating power by generating a power generator and a generator (1) vertical-type full-blade water gravity turbine (8P) 161-180 sets.   6 types of moving blade groups, each made of wear-resistant super-water-repellent plating (3a), with cylindrical annulus assembly (9A) + magnetic utilization bearing load approaching 0 + horizontal axis (1h) with super-high speed circumferential speed double-reversed Various energy storage cycle coalescence engines and coalescence methods for generating a power generator and a generator (1) to drive a vertical all blade hydrogravity turbine (8P) 181 to 200 sets.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 20 sets of vertical all-blade water gravity turbines (8P) driven by a counter rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating power from 21 to 40 sets of vertical rotor blades and gravity turbines (8P) driven by counter-rotating drive or generator (1) driven by a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating 41 to 60 sets of vertical rotor blades and gravity gravity turbines (8P) driven by counter-rotating drive or generator (1) driven by a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating 61-80 sets of vertical all-blade hydrogravity turbines (8P) driven by a counter rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for generating 100-100 sets of vertical all-blade water gravity turbine (8P) driven by counter-rotating drive and generator (1) driven by a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engines and coalescence methods for generating power by rotating a reverse all-rotary blade water gravity turbine (8P) 101-120 sets driven by a counter-rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engines and coalescence methods for generating a pair of full-rotating blade hydrogravity turbines (8P) 121 to 140 driven by a counter rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engines and coalescence methods for generating a pair of full-rotating blade hydrogravity turbines (8P) 141-160 driven by a counter rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods for generating a power generation with a vertical reversal blade hydrogravity turbine (8P) 161-180 driven by a counter rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of rotor blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical ring assembly (9A) + magnetic bearing load 0 approach + water (3E) Mach 1-30 with super high speed circumferential speed Various energy storage cycle coalescing engines and coalescence methods for generating a power generator 181 to 200 sets of vertical-type full-rotation blade water gravity turbines (8P) driven by a counter-rotating drive or a generator (1) on a horizontal axis (1h) driven by injection.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 20 sets of vertical all blade hydrogravity turbines (8P) driven by a counter-rotating drive or a generator (1) by a driven horizontal axis (1h).   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescing engines and coalescence methods for generating power in a pair of full-rotating blade water gravity turbines (8P) 21 to 40 driven by a counter-rotating drive or a generator (1) driven by a horizontal axis (1h) to be driven   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating 41-60 sets of vertical rotor blades and gravity gravity turbines (8P) driven by a counter-rotating drive or a generator (1) on a driven horizontal axis (1h).   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating 61-80 sets of vertical all-blade hydrogravity turbines (8P) driven by a counter-rotating drive or a generator (1) driven by a horizontal axis (1h) to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engine and coalescence method for generating 100-100 sets of vertical all-blade hydrogravity turbine (8P) driven by counter-rotating drive or generator (1) driven by a horizontal axis (1h) to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating power by rotating the reverse axis drive (1h) on the horizontal axis (1h) and the vertical rotor blade water gravity turbine (8P) 101 to 120 driven by the generator (1).   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating a pair of full-rotating blade hydrogravity turbines (8P) 121 to 140 driven by a counter-rotating drive or a generator (1) driven by a horizontal axis (1h) to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating a pair of full-rotating blade water gravity turbines (8P) 141 to 160 sets driven by a counter-rotating drive and a generator (1) driven by a horizontal axis (1h) to be driven.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescence engines and coalescence methods for generating power by reverse reversal drive on a horizontal axis (1h) to be driven and vertical type moving blade water gravity turbine (8P) 161 to 180 sets driven by a generator (1).   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical annular assembly (9A) + magnetic bearing load approaching 0 + water (3E) with super high speed circumferential speed, aiming at Mach 30 Various energy storage cycle coalescing engines and coalescence methods for generating a pair of full-rotating blade hydrogravity turbines (8P) 181 to 200 sets driven by a counter-rotating drive or a generator (1) on a driven horizontal axis (1h).   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles for generating power from 1 to 20 sets of vertical all-blade hydrogravity turbine (8P) driven by counter-rotating or generator (1) on the horizontal axis (1h) driven for acceleration by Mach 30 Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles to generate power from 21 to 40 sets of vertical all-blade hydrogravity turbine (8P) driven by counter-rotating drive or generator (1) driven by a horizontal axis (1h) driven by Mach 30 for acceleration of injection Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy storage cycles for generating 41-60 sets of vertical all-blade water gravity turbines (8P) driven by counter-rotating and generator (1) driven by the horizontal axis (1h) driven by Mach 30 for acceleration of injection Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles for generating power from 61 to 80 sets of vertical all-blade water gravity turbine (8P) driven by counter-rotating or generator (1) driven by the horizontal axis (1h) driven by Mach 30 for acceleration of injection Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles for generating power from a vertical all-blade water-gravity turbine (8P) 81 to 100 sets driven by a counter-rotating drive or a generator (1) on the horizontal axis (1h) driven by Mach 30 for acceleration of injection Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles for generating a power generation of a vertical all-blade water-gravity turbine (8P) 101 to 120 sets driven by a counter-rotating drive or a generator (1) on a horizontal axis (1h) driven for injection acceleration aiming at Mach 30 Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy storage cycles for generating power by vertical reversal blade water gravity turbine (8P) 121-140 sets driven by counter-rotating drive and generator (1) on the horizontal axis (1h) driven by Mach 30 for acceleration of injection Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles to generate power by vertical reverse rotor water gravity turbine (8P) 141 to 160 sets driven by counter-rotating drive or generator (1) on the horizontal axis (1h) driven by injection acceleration aiming at Mach 30 Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy storage cycles for generating power in a vertical all-blade hydrogravity turbine (8P) 161-180 sets driven by counter rotation or generator (1) on the horizontal axis (1h) driven for injection acceleration aiming at Mach 30 Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various energy conservation cycles for generating power from a wing-type full-blade hydrogravity turbine (8P) 181 to 200 sets driven by counter-rotating drive and generator (1) driven by the horizontal axis (1h) driven by Mach 30 for acceleration of injection Merger engine and merger method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power generation of double-rotating blade hydrogravity turbine (8P) 1-20 sets driven by counter rotation or generator (1) on the horizontal axis (1h) driven by Mach 1-30 for acceleration of injection Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power generation by double reversal drive on horizontal axis (1h) driven by Mach 1-30 and driven by generator (1), vertical type moving blade water gravity turbine (8P) 21-40 sets Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage for generating 41-60 sets of vertical-type full-blade water gravity turbine (8P) driven by counter-rotating drive and generator (1) driven by a horizontal axis (1h) driven by Mach 1-30 by injection acceleration Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy conservation to generate power from a vertical all-blade hydrogravity turbine (8P) 61 to 80 sets driven by a counter-rotating drive or a generator (1) driven by a horizontal axis (1h) driven by Mach 1 to 30 by injection acceleration Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power generation by vertical reversal blade hydrogravity turbine (8P) 81-100 driven by counter rotating drive or generator (1) driven by horizontal axis (1h) driven by Mach 1-30 by injection acceleration Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to make power generation by vertical reversal blade water gravity turbine (8P) 101-120 sets driven by counter-rotating drive or generator (1) by horizontal axis (1h) driven by Mach 1-30 by acceleration Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power generation by double reversal drive on horizontal axis (1h) driven by injection at Mach 1-30 or vertical-type full-blade water gravity turbine (8P) driven by generator (1) 121-140 sets Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power generation by double reversal drive on the horizontal axis (1h) driven by Mach 1-30 and driven by generator (1), vertical-type full-blade water gravity turbine (8P) 141-160 sets Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power generation by vertical reversal blade hydrogravity turbine (8P) 161-180 sets driven by counter-rotating drive or generator (1) by horizontal axis (1h) driven by Mach 1-30 by injection acceleration Cycle coalescence engine and coalescence method.   Each of the six types of blade groups, which are wear-resistant super-water-repellent plating (3a), has a cylindrical annular assembly (9A) + a magnetic bearing load of 0 approach + an ultra-high speed circumferential speed. 3E) Various types of energy storage to generate power in a double-rotating blade hydrogravity turbine (8P) 181 to 200 sets driven by a counter-rotating drive or a generator (1) on a horizontal axis (1h) driven by Mach 1 to 30 for acceleration of injection Cycle coalescence engine and coalescence method.   Inlet blade of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are wear-resistant superhydrophobic plating (3a) by fixing the inlet fixed outer blade (60E) annular fitting assembly. Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 200 sets of vertical type moving blade water gravity turbines (8P) having a magnetic bearing load of 0 approaching + super high speed circumferential speed constituting the group.   Inlet blade of the cylindrical inner blade group (60C) in which the inner shaft device (60A) and the cylindrical annular assembly (9A) are wear-resistant super water-repellent plating (3a) by fixing the inlet fixed inner blade (60F) annular fitting assembly. Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 200 sets of vertical type moving blade water gravity turbines (8P) having a magnetic bearing load of 0 approaching + super high speed circumferential speed constituting the group.   The outer intermediate blade group of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are made of an outer annular blade (60G) annular fitting assembly and wear-resistant super-water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for generating a power generation of a vertical all blade hydrogravity turbine (8P) 1 to 200 sets having a magnetic bearing load of 0 approaching + super high speed circumferential speed.   Inner intermediate blade group of cylindrical inner blade group (60C) in which inner shaft device (60A) and cylindrical annular assembly (9A) are wear-resistant super-water-repellent plating (3a) by inner annular blade (60H) annular fitting assembly. Various energy storage cycle coalescence engine and coalescence method for generating a power generation of a vertical all blade hydrogravity turbine (8P) 1 to 200 sets having a magnetic bearing load of 0 approaching + super high speed circumferential speed.   The outer intermediate blade group of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are made of an outer annular blade (60G) annular fitting assembly and wear-resistant super-water-repellent plating (3a). Two or more energy storage cycle coalescence engines and coalescence methods for generating 1 to 200 sets of vertical rotor blade water gravity turbine (8P) with a magnetic bearing load of 0 approach + super high speed circumferential speed.   Inner intermediate blade group of cylindrical inner blade group (60C) in which inner shaft device (60A) and cylindrical annular assembly (9A) are wear-resistant super-water-repellent plating (3a) by inner annular blade (60H) annular fitting assembly. Two or more energy storage cycle coalescence engines and coalescence methods for generating 1 to 200 sets of vertical rotor blade water gravity turbine (8P) with a magnetic bearing load of 0 approach + super high speed circumferential speed.   Outlet blades of the cylindrical inner blade group (60C) in which the inner shaft device (60A) and the cylindrical annular assembly (9A) are made of an abrasion-fixed superhydrophobic plating (3a) by fixing the outlet fixed inner blade (60K) annular fitting assembly. Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 200 sets of vertical type moving blade water gravity turbines (8P) having a magnetic bearing load of 0 approaching + super high speed circumferential speed constituting the group.   Outlet blades of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are wear-resistant super water-repellent plating (3a) by fixing the outlet fixed outer blade (60J) to the annular fitting assembly. Various energy storage cycle coalescence engines and coalescence methods for generating 1 to 200 sets of vertical type moving blade water gravity turbines (8P) having a magnetic bearing load of 0 approaching + super high speed circumferential speed constituting the group.   The next outer shaft device (60B) + the outer side of the cylinder is driven by connecting the outer shaft device (60B) + the cylindrical outer blade group (60D) made of the wear-resistant super-water-repellent plating (3a) with a horizontal shaft (1h) gear. For the vertical power blade hydrogravity turbine (8P) 1 to 200 sets of power generation with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed with the rotating direction of the rotating blade group (60D) rotating in the reverse direction to minimize resonance and noise Various energy storage cycle coalescence engine and coalescence method.   The next outer shaft device (60B) + the outer side of the cylinder is driven by connecting the outer shaft device (60B) + the cylindrical outer blade group (60D) made of the wear-resistant super-water-repellent plating (3a) with a horizontal shaft (1h) gear. Rotor blade group (60D) A vertical all-blade blade with a rotation of the rotating direction opposite to that of the inner shaft device (60A) and a counter-rotating rotation of the rotating blade group (60D). Various energy storage cycle coalescence engine and coalescence method for generating 1 to 200 sets of water gravity turbine (8P).   A vertical all-blade hydrogravity turbine (8P) with a solar heater (21) provided with buoyancy on the water surface, and solar heated air with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed. Low-cost electricity-driven electric drive, 1 to multi-stage heat pump (1G) compresses several times with suction, and heat is recovered with 1 to multi-stage compression heat recovery unit (2C) for each compression, electricity + liquid air cold heat + hot water -Various energy storage cycle coalescence engine and coalescence method to make superheated steam temperature supply equipment (3D).   A solar heater (21) is provided with buoyancy on the water surface, and a rotation support part (4f) for controlling rotation of the sunlight at right angles from east to west is provided, and the solar heating air is used as a magnetic bearing load. Vertically moving blade hydrogravity turbine (8P) with zero approach + super high speed circumferential speed (8P) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G), compressed multiple times, 1 to each compression Various energy storage cycle coalescence engines and coalescence methods that recover heat with a multi-stage compression heat recovery device (2C) to make electricity + liquid air cold heat + hot water to superheated steam temperature heat supply equipment (3D).   The solar heater (21) is provided with buoyancy on the water surface, and includes a rotation support part (4f) that controls rotation of the sunlight at a right angle from east to west, and includes a gear device (4d) and a roller (4e). ) As a cylindrical rotating part (77G), a vertical rotating blade hydrogravity turbine in which sunlight is rotated and maintained at a right angle in the vertical direction, and the solar heating air has a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed. (8P) Extremely inexpensive electricity-driven electric drive, 1 to multi-stage heat pump (1G) compresses by suction multiple times, and heat is recovered by 1 to multi-stage compression heat recovery unit (2C) for each compression, electricity + liquid Various energy storage cycle coalescence engines and coalescence methods for making air cold heat + hot water to superheated steam heat supply equipment (3D).   The solar heater (21) is provided with buoyancy on the water surface, and includes a rotation support part (4f) that controls rotation of the sunlight at a right angle from east to west, and includes a gear device (4d) and a roller (4e). ) As a cylindrical rotating part (77G), as a device for controlling rotation of the sunlight at a right angle in the vertical direction and as a device for controlling rotation at a right angle in the east-west direction by using buoyancy, the sunlight is linearly irradiated around the center of the heat absorption tube (4H). A vertical multi-blade hydrogravity turbine (8P) with a maximum air (28a) temperature, a magnetic bearing load approaching 0 and a super-high speed circumferential speed. ), Multiple times of suction, and heat recovery with 1 to multi-stage compression heat recovery unit (2C) for each compression, to save various energy into electricity + liquid air cold heat + hot water to superheated steam temperature supply equipment (3D) Cycle coalescence engine and coalescence method.   The solar heater (21) is provided with buoyancy on the water surface, and includes a rotation support part (4f) that controls rotation of the sunlight at a right angle from east to west, and includes a gear device (4d) and a roller (4e). ) As a cylindrical rotating part (77G), as a device for controlling rotation of the sunlight at a right angle in the vertical direction and as a device for controlling rotation at a right angle in the east-west direction by using buoyancy, the sunlight is linearly irradiated around the center of the heat absorption tube (4H). A vertical full-blade hydrogravity with maximum air (28a) temperature and external air (28a) heating each air passage (28A) as a high temperature selective suction, with magnetic bearing load approaching 0 + super high speed circumferential speed Turbine (8P) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G) compresses several times with suction, and for each compression heat is recovered with 1 to multi-stage compression heat recovery device (2C), Liquid air cooling + hot water to superheated steam Various energy conservation cycle combined institutions and coalescence how to supply equipment (3D).   A vertical all-blade hydrogravity turbine (8P) extreme equipped with a solar heater (21) with a circular railroad on a flat ground, and using solar heated air with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Compressed electricity multiple times with 1 to multiple stage heat pump (1G), and recovers heat with 1 to multiple stage compression heat recovery unit (2C) for each compression, electricity + liquid air cold + high temperature Various energy storage cycle coalescence engines and coalescence methods for water to superheated steam temperature supply equipment (3D).   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling and rotating the sunlight at a right angle from east to west, and the solar heating air is used as a magnetic bearing. Vertically moving blade water gravity turbine (8P) with a load approaching 0 and an ultra-high speed circumferential speed (8P) Compressed by suction multiple times with 1 to multi-stage heat pump (1G) of extremely inexpensive power generation electric drive, 1 for each compression ~ Various energy storage cycle coalescence engine and coalescence method to recover heat with multi-stage compression heat recovery device (2C) to make electricity + liquid air cold heat + hot water ~ superheated steam temperature heat supply equipment (3D).   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling rotation of the sunlight at a right angle from east to west, and a gear device (4d) and a roller ( 4e) As a cylindrical rotating part (77G), a vertical rotating blade water gravity is obtained by using a device that controls rotation by maintaining sunlight at a right angle in the vertical direction, and using solar heated air with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed. Turbine (8P) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G) compresses several times with suction, and for each compression heat is recovered with 1 to multi-stage compression heat recovery device (2C), Liquid energy cold heat + high temperature water to superheated steam temperature supply facility (3D) Various energy storage cycle coalescing engines and coalescence methods.   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling rotation of the sunlight at a right angle from east to west, and a gear device (4d) and a roller ( 4e) is used as a cylindrical rotating part (77G) as a device for controlling and rotating sunlight at a right angle in the vertical direction, and as a device for controlling rotation at a right angle in the east and west direction by using a circular railway, sunlight is linearly centered on the heat absorption tube (4H). A vertical multi-blade hydrogravity turbine (8P) with a maximum irradiation internal air (28a) temperature and a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed. Various (1G) suction multiple times compression, heat recovery with 1 to multi-stage compression heat recovery device (2C) for each compression, to make electricity + liquid air cold heat + hot water to superheated steam temperature heat supply equipment (3D) Energy conservation cycle coalescence engine and coalescence Method.   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling rotation of the sunlight at a right angle from east to west, and a gear device (4d) and a roller ( 4e) is used as a cylindrical rotating part (77G) as a device for controlling and rotating sunlight at a right angle in the vertical direction, and as a device for controlling rotation at a right angle in the east and west direction by using a circular railway, sunlight is linearly centered on the heat absorption tube (4H). A vertical all-blade with maximum temperature of the internal air (28a) irradiated and the external air (28a) heated to each air passage (28A) as a high-temperature selective suction with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G) compresses several times with suction, and for each compression heat recovery with 1 to multi-stage compression heat recovery device (2C), Electricity + liquid air cooling + superheated steam temperature Various energy saving cycles combined engine and coalescence process for the electrical + liquid air cold + hot water - superheated steam heat supply facilities (3D) to supply equipment 3D.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive and collect superheated steam hot methane injection into methane hydrate on the sea floor.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods for collecting superheated steam hot-heated methane into liquid methane hydrate on the seabed with liquid nitrogen (5 L) cooled liquid methane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy conservation cycle coalescence engines and coalescence methods that receive and collect superheated steam hot-injected methane in methane hydrate under permafrost.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive and collect superheated steam hot-injected methane in methane hydrate under permafrost with liquid nitrogen (5 L) cooled liquid methane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy conservation cycle coalescence engines and coalescence methods that are received from methane hydrate under permafrost to provide superheated steam heat injection enclosures for methane recovery and pasture grazing projects.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that are received and collected by providing a superheated steam injection enclosure in the oil sand zone.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that are received and collected by collecting superheated steam injection in an oil shale zone.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that are received and collected by providing an overheated steam injection enclosure in an old oil extraction zone.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that are received more and in the food manufacturing industry, etc., receive superheated steam at low cost to produce mass foods at low cost.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper superheated steam and use it for agriculture, industrial, industrial and mining industries to make the best use of thermal energy.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and setting the compression volume to 21/60000 of air compression Theoretical combustion chamber (4Q) aiming at ultrahigh pressure combustion Theoretical expansion engine (3Q) is driven as ultrahigh pressure fuel combustion and the vehicle is driven Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Various energy storage cycle coalescence engines and coalescence methods that drive the theoretical expansion engine (3Q) as ultrahigh pressure fuel combustion and drive the vehicle .   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + high-temperature water and aims at ultra-high pressure combustion (4Q) Theoretical expansion engine (3Q) as an ultra-high pressure fuel combustion and various energy storage cycle coalescence engines that are driven by automobiles And coalescing method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aimed at ultra high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) drive generator (1) Various energy storage cycle coalescence engines and coalescence methods that store electricity in the drive storage battery (1A) and drive the storage battery drive wheels (4J) rotation theoretical expansion engine automobile (4L).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity and storing in the theoretical expansion engine (3Q) driven generator (1) driven storage battery (1A) as the theoretical combustion chamber (4Q) ultra high pressure fuel combustion aiming at ultra high pressure combustion Various energy storage cycle coalescence engine and coalescence method for driving storage battery drive wheel (4J) rotation theory expansion engine automobile (4L).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + hot water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) Drive generator (1) Drive battery (1A) Various energy storage cycle coalescence engine and coalescence method for storing and driving a storage battery drive wheel (4J) rotation theoretical expansion engine automobile (4L).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aimed at ultra high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) drive generator (1) Various energy storage cycle coalescence engine and coalescence method for driving a theoretical expansion engine automobile (4L) capable of accumulating power in the drive storage battery (1A) and rotating the storage battery drive wheel (4J) and normal wheel.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity and storing in the theoretical expansion engine (3Q) driven generator (1) driven storage battery (1A) as the theoretical combustion chamber (4Q) ultra high pressure fuel combustion aiming at ultra high pressure combustion Various energy storage cycle coalescence engine and coalescence method for driving a theoretical expansion engine automobile (4L) capable of rotating a battery drive wheel (4J) and rotating a normal wheel.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + hot water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) Drive generator (1) Drive battery (1A) Various energy storage cycle coalescence engines and coalescence methods for driving a theoretical expansion engine automobile (4L) capable of storing and rotating storage battery drive wheels (4J) and normal wheels.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion engine (3Q) is driven as the theoretical combustion chamber (4Q) super high pressure fuel combustion aiming at super high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Various energy storage cycle coalescence engines and coalescence methods for driving automobiles (4L).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Drives the theoretical expansion engine (3Q) as ultra-high pressure fuel combustion and screw (7C ) Various energy storage cycle coalescence engines and coalescence methods for driving a rotating ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion (4Q) Various energy conservation cycles that drive the theoretical expansion engine (3Q) and drive the screw (7C) as super high pressure fuel combustion Merger engine and merger method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion, various types of driving a theoretical expansion engine (3Q) and a screw (7C) rotating ship as ultra-high pressure fuel combustion Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. Various energy storage cycle coalescence engine and coalescence method for driving a screw (7C) multiple rotation ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion, 1 to multiple driving of theoretical expansion engine (3Q) as a high-pressure fuel combustion, screw (7C) multiple-rotation ship drive Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + high-temperature water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drives and screws (7C) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for driving a ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. Various energy storage cycle coalescence engine and coalescence method for driving screw (7C) multi-rotation oxygen coalescence screw ship (39Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive and screw (7C) multiple rotation oxygen combined screw as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for driving a ship (39Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + high-temperature water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drives and screws (7C) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving oxygen coalescence screw ship (39Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion Drive the theoretical expansion engine (3Q) as ultra high pressure fuel combustion and oxygen combined screw Various energy storage cycle coalescence engines and coalescence methods for driving a ship (39Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Drives the theoretical expansion engine (3Q) as ultra-high pressure fuel combustion and screw (7C ) Rotating oxygen coalescence water injection unit (88L) Various energy storage cycle coalescence engines and coalescence methods for driving jet propulsion vessels.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, theoretical combustion chamber (4Q) aiming for ultra high pressure combustion, driving theoretical expansion engine (3Q) as ultra high pressure fuel combustion, screw (7C) rotary oxygen combined water injection part (88L ) Various energy storage cycle coalescing engines and coalescence methods for driving jet propulsion vessels.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high temperature water, theoretical combustion chamber (4Q) aiming for ultra high pressure combustion, theoretical expansion engine (3Q) as ultra high pressure fuel combustion, screw (7C) rotating oxygen combined water injection (88L) injection propulsion ship various energy storage cycle coalescing engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. Various energy storage cycle coalescence engine and coalescence method for driving a screw (7C) multi-rotation oxygen coalescence water injection part (88L) injection propulsion ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive and screw (7C) multiple rotation oxygen combined water as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving an injection unit (88L) jet propulsion ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + high-temperature water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drives and screws (7C) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving oxygen coalescence water injection part (88L) injection propulsion ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. Various energy storage cycle coalescence engine and coalescence method for driving screw (7C) multi-rotation oxygen coalescence water injection section (88L) injection propulsion oxygen coalescence screw injection vessel (39S).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive and screw (7C) multiple rotation oxygen combined water as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for driving the injection section (88L) injection propulsion oxygen coalescence screw injection vessel (39S).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + high-temperature water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drives and screws (7C) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for driving an oxygen coalescence water injection section (88L) injection propulsion oxygen coalescence screw injection vessel (39S).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. The theoretical expansion engine (3Q) is driven as super high pressure fuel combustion and oxygen combined water Various energy storage cycle coalescence engines and coalescence methods for driving the injection section (88L) injection propulsion oxygen coalescence screw injection vessel (39S).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that aims to receive low-cost liquid oxygen (5K) and the compression volume is 21/60000 of air compression. ) Various energy storage cycle coalescing engines and coalescence methods for driving jet propulsion vessels.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, theoretical combustion chamber (4Q) aiming for streamlined ultra-high pressure combustion, oxygen combined water injection part (88L) injection propulsion with ultra-high pressure multiple fuel combustion injection propulsion, various energy storage to drive the ship Cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, streamlined ultra high pressure combustion aiming theoretical combustion chamber (4Q) super high pressure multiple fuel combustion injection propulsion oxygen combined water injection part (88L) injection propulsion ship drive Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), oxygen is made into a multi-high pressure fuel combustion injection propulsion including a theoretical combustion chamber (4Q) air suction flow channel aiming at a streamlined ultra-high pressure combustion with a compression volume of 21/60000 of air compression Combined water injection unit (88L) injection propulsion ship, various energy storage cycle combining engine and combining method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water injection unit (88L) injection propulsion that receives low-cost liquid oxygen (5K) + electricity, and has a theoretical combustion chamber (4Q) air suction flow channel aiming at streamline type ultra-high pressure combustion, and multiple ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engines and coalescence methods for driving a ship.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water injection unit (88L) which receives low-priced liquid oxygen (5K) + electricity + high-temperature water and has a superficial combustion chamber (4Q) air suction flow path aiming at streamline type ultra-high pressure combustion and a plurality of ultra-high pressure fuel combustion injection propulsion ) Various energy storage cycle coalescing engines and coalescence methods for driving jet propulsion vessels.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), oxygen is made into a multi-high pressure fuel combustion injection propulsion including a theoretical combustion chamber (4Q) air suction flow channel aiming at a streamlined ultra-high pressure combustion with a compression volume of 21/60000 of air compression Combined water injection unit (88L) injection propulsion oxygen combination injection ship (39R) various energy storage cycle combination engine and combination method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water injection unit (88L) injection propulsion that receives low-cost liquid oxygen (5K) + electricity, and has a theoretical combustion chamber (4Q) air suction flow channel aiming at streamline type ultra-high pressure combustion, and multiple ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engines and coalescence methods for driving an oxygen coalescence injection ship (39R).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water injection unit (88L) which receives low-priced liquid oxygen (5K) + electricity + high-temperature water and has a superficial combustion chamber (4Q) air suction flow path aiming at streamline type ultra-high pressure combustion and a plurality of ultra-high pressure fuel combustion injection propulsion ) Various types of energy storage cycle coalescence engine and coalescence method for driving an injection propulsion oxygen coalescence injection ship (39R).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and setting the compression volume to 21/60000 of air compression Streamlined ultra-high pressure combustion aiming at multiple theoretical combustion chambers (4Q) oxygen combined water injection unit (88L) injection propulsion oxygen combined injection Various energy storage cycle coalescence engines and coalescence methods for driving a ship (39R).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that aims to receive low-cost liquid oxygen (5K) and the compression volume is 21/60000 of air compression. ) Various energy conservation cycle coalescence engines and coalescence methods for making jet propulsion airplanes.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, theoretical combustion chamber (4Q) aiming at streamlined ultra high pressure combustion, oxygen combined air injection unit (88B) with multiple ultra high pressure fuel combustion injection propulsion and various energy conservation Cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, a theoretical combustion chamber (4Q) aiming at streamlined ultra-high pressure combustion, oxygen-combined air injection unit (88B) injection propulsion airplane with multiple ultra-high pressure fuel combustion injection propulsion Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), oxygen is made into a multi-high pressure fuel combustion injection propulsion including a theoretical combustion chamber (4Q) air suction flow channel aiming at a streamlined ultra-high pressure combustion with a compression volume of 21/60000 of air compression Various energy storage cycle coalescence engine and coalescence method to make a coalescence air injection unit (88B) jet propulsion airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air injection unit (88B) injection propulsion that receives low-cost liquid oxygen (5K) + electricity and has a theoretical combustion chamber (4Q) air suction flow channel that aims at streamlined ultra-high pressure combustion and includes multiple ultrahigh pressure fuel combustion injection propulsion Various energy conservation cycle coalescence engines and coalescence methods for airplanes.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air injection unit (88B) that receives low-priced liquid oxygen (5K) + electricity + high-temperature water and has a superficial combustion chamber (4Q) air suction channel that aims at streamlined ultra-high pressure combustion and includes multiple ultra-high pressure fuel combustion injection propulsion ) Various energy conservation cycle coalescence engines and coalescence methods for making jet propulsion airplanes.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), oxygen is made into a multi-high pressure fuel combustion injection propulsion including a theoretical combustion chamber (4Q) air suction flow channel aiming at a streamlined ultra-high pressure combustion with a compression volume of 21/60000 of air compression Various energy storage cycle coalescence engines and coalescence methods for driving the coalescence air injection section (88B) injection propulsion oxygen coalescence injection airplane (39T).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air injection unit (88B) injection propulsion that receives low-cost liquid oxygen (5K) + electricity and has a theoretical combustion chamber (4Q) air suction flow channel that aims at streamlined ultra-high pressure combustion and includes multiple ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engines and coalescence methods for driving an oxygen coalescence jet airplane (39T).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air injection unit (88B) that receives low-priced liquid oxygen (5K) + electricity + high-temperature water and has a superficial combustion chamber (4Q) air suction channel that aims at streamlined ultra-high pressure combustion and includes multiple ultra-high pressure fuel combustion injection propulsion ) Various energy storage cycle coalescence engine and coalescence method for driving an injection propulsion oxygen coalescence aircraft (39T).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Streamlined ultra-high pressure combustion aiming at the theoretical combustion chamber (4Q) multiple oxygen coalescence air injection unit (88B) injection propulsion oxygen coalescence injection Various energy storage cycle coalescence engines and coalescence methods for driving an airplane (39T).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Drives the theoretical expansion engine (3Q) as ultra-high pressure fuel combustion and propeller (7A ) Various energy storage cycle coalescence engines and coalescence methods that drive a rotating airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion (4Q) Various energy storage cycles driven by a theoretical expansion engine (3Q) and propeller (7A) rotating airplane as ultra high pressure fuel combustion Merger engine and merger method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high temperature water, theoretical combustion chamber (4Q) aiming at ultra high pressure combustion, various types of driving a propeller (7A) rotating airplane by driving theoretical expansion engine (3Q) as ultra high pressure fuel combustion Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. Propeller (7A) Various energy storage cycle coalescence engine and coalescence method for driving a multi-turn airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, theoretical combustion chamber (4Q) aiming at ultra high pressure combustion, 1 to multiple driving of theoretical expansion engine (3Q) and propeller (7A) multiple rotation airplane driving Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + hot water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive and propeller (7A) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving an airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the compression volume is 21/60000 of air compression. Theoretical combustion chamber (4Q) aiming at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods for driving a propeller (7A) multi-rotation oxygen coalescence propeller airplane (39U).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra-high pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive propeller (7A) multi-rotation oxygen combined propeller as ultra-high pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for driving an airplane (39U).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + hot water and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive and propeller (7A) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods driven by an oxygen coalescence propeller airplane (39U).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Drives the theoretical expansion engine (3Q) as ultra-high pressure fuel combustion and propeller (7A ) Various energy storage cycle coalescence engines and coalescence methods driven by a rotary oxygen coalescence propeller airplane (39U).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aimed at ultrahigh pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) driven rotor blade (7B) Various energy storage cycle coalescence engines and coalescence methods that rotate and drive the aircraft.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, theoretical combustion chamber (4Q) aiming for ultra-high pressure combustion, theoretical expansion engine (3Q) driven rotor blade (7B) as ultra high pressure fuel combustion, various energy storage to drive airplane Cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, theoretical combustion chamber (4Q) aiming at ultrahigh pressure combustion Theoretical expansion engine (3Q) driven rotor blades (7B) rotate as an ultrahigh pressure fuel combustion to drive the airplane Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion which receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) 1 to multiple drive rotor blades (7B) Various energy storage cycle coalescing engines and coalescence methods for driving a plurality of revolutions to drive an airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive rotor blades (7B) multiple revolutions as airplane drive Various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, theoretical combustion chamber (4Q) aiming for ultrahigh pressure combustion, the theoretical expansion engine (3Q) 1 to multiple drive rotor blades (7B) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods that drive aircraft.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion which receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) 1 to multiple drive rotor blades (7B) Various energy storage cycle coalescence engines and coalescence methods for driving the oxygen coalesced rotor blade airplane (39P) by multiple rotations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1 to multiple drive rotor blades (7B) multiple rotations as oxygen coalescence Various energy storage cycle coalescence engines and coalescence methods for driving a rotary wing airplane (39P).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, theoretical combustion chamber (4Q) aiming for ultrahigh pressure combustion, the theoretical expansion engine (3Q) 1 to multiple drive rotor blades (7B) multiple rotations as ultrahigh pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods that drive oxygen coalesced rotorcraft (39P).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aimed at ultrahigh pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) driven rotor blade (7B) Various energy storage cycle coalescence engines and coalescence methods that rotate and drive oxygen coalesced rotorcraft (39P).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) drive propeller (7A) rotation Oxygen coalescence air injection unit (88B) Various energy storage cycle coalescence engines and coalescence methods for driving an injection propulsion airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra-high pressure combustion (4Q) Theoretical expansion engine (3Q) drive propeller (7A) rotates as an ultra-high pressure fuel combustion and oxygen combined air injection unit (88B) Various energy storage cycle coalescing engines and coalescence methods for driving jet propulsion airplanes.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + hot water and aims at ultrahigh pressure combustion (4Q) Theoretic expansion engine (3Q) drive propeller (7A) rotates as an ultrahigh pressure fuel combustion and oxygen combined air injection unit (88B) Various energy storage cycle coalescence engines and coalescence methods for driving an injection propulsion airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. 7A) Various energy storage cycle coalescence engines and coalescence methods that rotate a plurality of times and drive an oxygen coalescence air injection unit (88B) injection propulsion airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1-multiple drive propeller (7A) multiple rotations and oxygen combined air injection (88B) Various energy storage cycle coalescence engine and coalescence method for driving an injection propulsion airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) receiving ultra-high pressure combustion by receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, theoretical expansion engine (3Q) 1-multiple drive propeller (7A) multiple rotation oxygen Combined air injection unit (88B) Various energy storage cycle combined engines and combined methods for driving an injection propulsion airplane.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. 7A) Various energy storage cycle coalescence engines and coalescence methods that rotate a plurality of times and drive an oxygen coalescence air injection unit (88B) injection propulsion oxygen coalescence propeller injection airplane (39N).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh pressure combustion (4Q) Theoretical expansion engine (3Q) 1-multiple drive propeller (7A) multiple rotations and oxygen combined air injection (88B) Various types of energy storage cycle coalescence engine and coalescence method for driving the propulsion oxygen coalescence propeller jet airplane (39N).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) receiving ultra-high pressure combustion by receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, theoretical expansion engine (3Q) 1-multiple drive propeller (7A) multiple rotation oxygen Various energy storage cycle coalescence engines and coalescence methods for driving the coalescence air injection unit (88B) injection propulsion oxygen coalescence propeller injection airplane (39N).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion that receives cheaper liquid oxygen (5K) and the compression volume is 21/60000 of air compression. Theoretical expansion engine (3Q) drive propeller (7A) rotation Various energy storage cycle coalescence engines and coalescence methods for driving the oxygen coalescence air injection section (88B) injection propulsion oxygen coalescence propeller injection airplane (39N).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and setting the compression volume to 21/60000 of the air compression Theoretical combustion chamber (4Q) high pressure high temperature combustion gas control valve (5a) open combustion gas as super high pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods in which a high-pressure high-temperature combustion gas (5M) is injected from an injection nozzle (6Y) to drive a theoretical expansion engine (3Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion High pressure high temperature combustion from the high pressure high temperature combustion gas control valve (5a) open combustion gas injection nozzle (6Y) as ultra high pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for injecting gas (5M) to drive a theoretical expansion engine (3Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) receiving ultra-high pressure combustion by receiving cheaper liquid oxygen (5K) + electricity + high-temperature water From the high-pressure high-temperature combustion gas control valve (5a) open combustion gas injection nozzle (6Y) Various energy storage cycle coalescence engines and coalescence methods for injecting high-pressure and high-temperature combustion gas (5M) to drive a theoretical expansion engine (3Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and setting the compression volume to 21/60000 of the air compression Theoretical combustion chamber (4Q) high pressure high temperature combustion gas control valve (5a) open combustion gas as super high pressure fuel combustion Various energies for driving a theoretical expansion engine (3Q) that injects high-pressure and high-temperature combustion gas (5M) from an injection nozzle (6Y) to rotate the upper expansion blade (8d) and lower expansion blade (8e) horizontally (1h). Storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion High pressure high temperature combustion from the high pressure high temperature combustion gas control valve (5a) open combustion gas injection nozzle (6Y) as ultra high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a theoretical expansion engine (3Q) in which gas (5M) is injected to rotate the upper expansion blade (8d) and the lower expansion blade (8e) horizontally (1h).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) receiving ultra-high pressure combustion by receiving cheaper liquid oxygen (5K) + electricity + high-temperature water From the high-pressure high-temperature combustion gas control valve (5a) open combustion gas injection nozzle (6Y) Various energy storage cycle coalescence engine and coalescence which drive a theoretical expansion engine (3Q) which injects high pressure and high temperature combustion gas (5M) to rotate the upper expansion blade (8d) and lower expansion blade (8e) horizontally (1h) Method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and setting the compression volume to 21/60000 of the air compression Theoretical combustion chamber (4Q) high pressure high temperature combustion gas control valve (5a) open combustion gas as super high pressure fuel combustion High-pressure high-temperature combustion gas (5M) is injected from the injection nozzle (6Y), and the upper expansion blade (8d) and the lower expansion blade (8e) are turned into the horizontal axis (1h) and the counter-rotating assembly turbine blade (8f) is the theoretical expansion engine. (3Q) Various energy storage cycle coalescence engines and coalescence methods to be driven.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion High pressure high temperature combustion from the high pressure high temperature combustion gas control valve (5a) open combustion gas injection nozzle (6Y) as ultra high pressure fuel combustion Various energy storage cycles in which gas (5M) is injected to drive the upper expansion blade (8d) and the lower expansion blade (8e) to the horizontal expansion shaft (1h), the counter-rotating assembly turbine blade (8f), the theoretical expansion engine (3Q) Merger engine and merger method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) receiving ultra-high pressure combustion by receiving cheaper liquid oxygen (5K) + electricity + high-temperature water From the high-pressure high-temperature combustion gas control valve (5a) open combustion gas injection nozzle (6Y) Various types of driving high-pressure high-temperature combustion gas (5M) to drive the upper expansion blade (8d) and lower expansion blade (8e) to the horizontal expansion shaft (1h), the counter-rotating assembly turbine blade (8f), and the theoretical expansion engine (3Q). Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression. Theoretical combustion chamber aiming at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve (5a) open air suction as ultra high pressure fuel combustion The combustion amount is increased, and the high-pressure high-temperature combustion gas (5M) is injected from the combustion gas injection nozzle (6Y), and the upper expansion blade (8d) and the lower expansion blade (8e) are turned on the horizontal axis (1h). 8f) Assembling theoretical expansion engine (3Q) Various energy storage cycle merging engines and merging methods for driving.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression. Theoretical combustion chamber aiming at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve (5a) open circumference as ultra high pressure fuel combustion Various energy storage cycle coalescing engines and coalescence methods for a theoretical expansion engine (3Q) that expands in the direction of 380 degrees.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion engine that receives cheaper liquid oxygen (5K) + electricity and aims at ultrahigh-pressure combustion (4Q) High-pressure high-temperature combustion gas control valve (5a) as an ultra-high-pressure fuel combustion Theoretical expansion engine that expands and expands 380 degrees in the circumferential direction (3Q) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high temperature water, high pressure high temperature combustion gas control valve (5a) expands and expands 380 degrees in the circumferential direction as a theoretical combustion chamber (4Q) ultra high pressure fuel combustion aimed at ultra high pressure combustion Various energy storage cycle coalescing engine and coalescence method for a theoretical expansion engine (3Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression. Theoretical combustion chamber aiming at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve (5a) open circumference as ultra high pressure fuel combustion Various energy storage cycle coalescing engines and coalescence methods for a theoretical expansion engine (3Q) that achieves maximum drive speed with 380 degree expansion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve as ultra high pressure fuel combustion (5a) Maximum driving speed with expansion of 380 degrees in the circumferential direction Various energy storage cycle coalescing engine and coalescence method for the theoretical expansion engine (3Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + high-temperature water and aims at ultra-high pressure combustion (4Q) high-pressure high-temperature combustion gas control valve (5a) as an ultra-high pressure fuel combustion Various energy storage cycle coalescing engines and coalescence methods for a theoretical expansion engine (3Q) with maximum driving speed.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression. Theoretical combustion chamber aiming at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve (5a) open circumference as ultra high pressure fuel combustion Various energy storage cycle coalescing engines and coalescence methods for a theoretical expansion engine (3Q) with maximum expansion at 380 degree expansion and counter inversion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and aims at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve as ultra high pressure fuel combustion (5a) Open circumferential direction 380 degree expansion and double reversal Various energy storage cycle coalescing engine and coalescence method for a theoretical expansion engine (3Q) with a maximum driving speed.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity + hot water and aims at ultra-high pressure combustion (4Q) high-pressure high-temperature combustion gas control valve (5a) as an ultra-high pressure fuel combustion Various energy storage cycle coalescing engines and coalescence methods for a theoretical expansion engine (3Q) that achieves maximum driving speed by counter rotation.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression. Theoretical combustion chamber aiming at ultra high pressure combustion (4Q) High pressure high temperature combustion gas control valve (5a) open circumference as ultra high pressure fuel combustion Various energy storage cycle coalescing engine and coalescence method to make the theoretical expansion engine (3Q) to double inversion and 380 degree expansion expansion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), compressing liquid together with liquid fuel (1c) and water (52a), aiming at ultra high pressure combustion in which ultra high pressure compression fuel injection combustion is performed with a compression volume of 21/60000 volume of air compression, etc. Various energy storage cycle coalescing engine and coalescence method for a theoretical combustion chamber (4Q).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Ultra-high pressure that receives cheaper liquid oxygen (5K) + electricity, compresses liquid together with liquid fuel (1c) and water (52a), and injects and burns ultra-high-pressure compressed fuel with air compression of 21/60000 volume, etc. Various energy storage cycle coalescing engine and coalescence method for a theoretical combustion chamber (4Q) aimed at combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receives cheaper liquid oxygen (5K) + electricity + hot water, compresses liquid with liquid fuel (1c) and water (52a), and compresses the compressed volume with ultra-high pressure compressed fuel injection combustion with 21/60000 volume of air compression, etc. Various energy storage cycle coalescence engine and coalescence method to make the theoretical combustion chamber (4Q) aiming at ultra high pressure combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engine that receives cheaper liquid oxygen (5K), compresses it with liquid fuel (1c) and water (52a), and heats it to the optimum temperature on the inner wall of the theoretical combustion chamber (4Q) aiming at ultra high pressure combustion And coalescing method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy conservation cycles that receive cheaper liquid oxygen (5K) + electricity, compress the liquid with liquid fuel (1c) and water (52a), and heat it to the optimum temperature on the inner wall of the theoretical combustion chamber (4Q) aimed at ultra high pressure combustion Merger engine and merger method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various cheaper liquid oxygen (5K) + electricity + hot water is received and heated to the optimum temperature on the inner wall of the theoretical combustion chamber (4Q) aiming at ultra high pressure combustion by liquid compression with liquid fuel (1c) and water (52a) Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), compressing liquid together with liquid fuel (1c) and water (52a) and aiming at ultra-high pressure combustion The inner wall of the theoretical combustion chamber (4Q) heating oxygen control valve (24D) + Various energy storage cycle coalescence engines and coalescence methods for opening the fuel control valve (25b) + superheated steam control valve (25).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) The oxygen control valve (24D) is heated to the optimum temperature on the inner wall of the theoretical combustion chamber (4Q) that receives liquid oxygen (5K) + electricity at a lower price and compresses the liquid fuel (1c) and water (52a) together with the liquid fuel (1c) and water (52a). ) + Fuel control valve (25b) + superheated steam control valve (25) to open various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Heat oxygen control to the optimum temperature at the inner wall of the theoretical combustion chamber (4Q) that receives liquid oxygen (5K) + electricity + high temperature water, compresses liquid together with liquid fuel (1c) and water (52a) and aims at ultra high pressure combustion Various energy storage cycle coalescence engines and coalescence methods for opening the valve (24D) + fuel control valve (25b) + superheated steam control valve (25).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receive oxygen oxygen (5K) + hot water at a lower price, compress liquid together with liquid fuel (1c) and water (52a), and heat the oxygen control valve to the optimum temperature on the inner wall of the theoretical combustion chamber (4Q) aiming for ultra high pressure combustion ( 24D) + Fuel control valve (25b) + Superheated steam control valve (25) with open received superheated steam and various energy storage cycle combined engines and combined methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) to the optimum temperature by burning more than 3000 ° C near the center of open oxygen fuel burner Various energy storage cycle coalescing engine and coalescence method to make the theoretical combustion chamber (4Q) aiming at super high pressure combustion to heat the peripheral superheated steam (50).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) at the optimum temperature Open oxygen fuel burner near the center more than 3000 ° C Various energy storage cycle coalescence engine and coalescence method to make the theoretical combustion chamber (4Q) aiming at ultra high pressure combustion that heats the outer superheated steam (50) by combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, open heated oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) to the optimum temperature Various energy storage cycle coalescence engine and coalescence method for a theoretical combustion chamber (4Q) aiming at ultra high pressure combustion that heats the outer superheated steam (50) by combustion at 3000 ° C or higher.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) to the optimum temperature by burning more than 3000 ° C near the center of open oxygen fuel burner Various energy storage cycle coalescing engine and coalescence method for making superheated combustion (4Q) aiming at super high pressure combustion aiming at the outer periphery superheated steam (50) by heating partly in the vicinity of suction pyrolysis electrolysis.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) at the optimum temperature Open oxygen fuel burner near the center more than 3000 ° C Various energy storage cycle coalescence engines and coalescence methods for heating the outer superheated steam (50) by combustion to a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion aiming at the suction pyrolysis electrolysis near the center.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, open heated oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) to the optimum temperature Various energy storage cycle coalescence engines and coalescence methods that heat the outer superheated steam (50) by combustion at 3000 ° C. or more to make a theoretical combustion chamber (4Q) aiming at ultra high pressure combustion aiming at part of the suction pyrolysis electrolysis near the center.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) to the optimum temperature by burning more than 3000 ° C near the center of open oxygen fuel burner Various energy storage cycle coalescing engines and coalescence methods for heating the outer superheated steam (50) to a theoretical combustion chamber (4Q) aiming at superheated combustion, which is partly heated near the center of heat generation by pyrolysis, electrolysis, oxygen and hydrogen.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) at the optimum temperature Open oxygen fuel burner near the center more than 3000 ° C Various energy storage cycle coalescence engines and coalescence methods for heating the superheated steam (50) at the periphery by combustion to a theoretical combustion chamber (4Q) aiming at super high pressure combustion aiming at combustion by suction pyrolysis electrolysis oxygen hydrogen increase combustion near the center.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, open heated oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) to the optimum temperature Heating the outer superheated steam (50) by combustion at 3000 ° C. or higher. Part of the energy storage cycle coalescence engine and coalescence method to make a theoretical combustion chamber (4Q) aiming at super high pressure combustion aiming at increased combustion by partial pyrolysis, electrolysis, oxygen and hydrogen .   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + hot water, heating oxygen control valve (24D) + fuel control valve (25b) + superheated steam control valve (25) at the optimum temperature Open oxygen fuel burner near the center 3000 ° C Various types of energy storage cycle coalescence engines that make the outer combustion superheated steam (50) including the received superheated steam by the above-mentioned combustion into a theoretical combustion chamber (4Q) aimed at superheated pyrolysis electrolysis oxygen hydrogen increase combustion aiming at the vicinity of the center, and Merge method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), various energy made into oxygen combined water injection part (88L) of combustion gas (49) injection acceleration injection with multiple in-series combustion chamber (4Q) aiming at ultra high pressure combustion Storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity and using a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion as a streamline type, a plurality of in-line combustion gas (49) injection accelerated injection oxygen combined water injection part (88L) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, the theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion is streamlined and has a plurality of series combustion gas (49) injection combined oxygen injection water injection unit (88L) ) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion is streamlined, and combustion gas (49) is provided in series with (4Q) inner wall or combustion flow inner wall (5d) oxygen + fuel + Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection unit (88L) that uses superheated steam heated at an optimum temperature.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, the combustion chamber (4) with a plurality of in-line combustion gas (49) with a streamlined theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion (4Q) inner wall and combustion flow inner wall (5d) oxygen + Energy storage cycle coalescence engine and coalescence method in an oxygen coalescence water injection part (88L) that uses fuel + superheated steam heated at an optimum temperature.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Received less expensive liquid oxygen (5K) + electricity + hot water, and the combustion chamber (4Q) and combustion flow inner wall (5d ) Oxygen + fuel + superheated steam heated at an optimum temperature and used as an oxygen coalescence water injection unit (88L), and various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion is streamlined, and combustion gas (49) is provided in series with (4Q) inner wall or combustion flow inner wall (5d) oxygen + fuel + Various energy storage cycle coalescence engine and coalescence method in the oxygen coalescence water injection part (88L) for heating the superheated steam at the optimum temperature to make the combustion chamber (4Q) combustion aiming at super high pressure combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, the combustion chamber (4) with a plurality of in-line combustion gas (49) with a streamlined theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion (4Q) inner wall and combustion flow inner wall (5d) oxygen + Energy storage cycle coalescence engine and coalescence method with oxygen coalescence water injection part (88L) for the combustion of theoretical combustion chamber (4Q) aiming at super high pressure combustion by heating the fuel + superheated steam at the optimum temperature.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Received less expensive liquid oxygen (5K) + electricity + hot water, and the combustion chamber (4Q) and combustion flow inner wall (5d ) Oxygen + fuel + superheated steam is heated to an optimal temperature to achieve super high pressure combustion and a theoretical combustion chamber (4Q) combustion or the like.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + hot water, the combustion chamber (4Q) and the combustion flow inner wall (5d) of the combustion gas (49) equipped with a plurality of in-line combustion chambers (4Q) aiming at ultra-high pressure combustion. Various energy storage cycle coalescence engine and coalescence method with oxygen coalescence water injection part (88L) to make superheated steam containing oxygen + fuel + received high temperature water to the optimum temperature by heating it to the ideal combustion chamber (4Q) combustion etc. .   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen + fuel + superheated steam at the optimum temperature on each inner wall and aiming for ultra high pressure combustion in the theoretical combustion chamber (4Q) near the center Oxyfuel combustion Overheated at 3000 ° C or more with multiple combustion Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection unit (88L) aimed at steam suction pyrolysis electrolysis.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and heats the oxygen + fuel + superheated steam at the optimum temperature on each inner wall to aim at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection part (88L) aimed at superheated steam suction pyrolysis electrolysis.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam on each inner wall at the optimum temperature and aiming for ultra high pressure combustion Oxyfuel combustion near the center of combustion chamber (4Q) 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in the oxygen coalescence water injection section (88L) aimed at superheated steam suction pyrolysis electrolysis by multiple combustion as described above.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen + fuel + superheated steam at the optimum temperature on each inner wall and aiming for ultra high pressure combustion in the theoretical combustion chamber (4Q) near the center Oxyfuel combustion Overheated at 3000 ° C or more with multiple combustion Various energy storage cycle coalescence engine and coalescence method in the oxygen coalescence water injection part (88L) aimed at steam suction pyrolysis electrolysis oxygen hydrogen hydrogen increase combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and heats the oxygen + fuel + superheated steam at the optimum temperature on each inner wall to aim at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection unit (88L) aimed at superheated steam suction pyrolysis electrolysis oxygen oxygen hydrogen increase combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam on each inner wall at the optimum temperature and aiming for ultra high pressure combustion Oxyfuel combustion near the center of combustion chamber (4Q) 3000 ° C Various energy storage cycle coalescence engine and coalescence method in the oxygen coalescence water injection part (88L) aimed at superheated steam suction pyrolysis electrolysis oxygen oxygen hydrogen increase combustion by multiple combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the oxygen + fuel + superheated steam is heated at the optimum temperature on each inner wall, aiming at ultra high pressure combustion, near the center of the combustion chamber (4Q) Oxyfuel combustion near 3000 ° C and burning at multiple temperatures Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection section (88L) that heat-injects superheated steam (50) of a flow inner wall (5d) high-temperature water heating pipe (5H).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and heats the oxygen + fuel + superheated steam at the optimum temperature on each inner wall to aim at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection section (88L) for heating and injecting superheated steam (50) of the combustion flow inner wall (5d) high-temperature water heating pipe (5H).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam on each inner wall at the optimum temperature and aiming for ultra high pressure combustion Oxyfuel combustion near the center of combustion chamber (4Q) 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in the oxygen coalescence water injection section (88L) for heating and injecting the superheated steam (50) of the combustion flow inner wall (5d) high-temperature water heating pipe (5H) by multiple combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + high-temperature water, oxygen + fuel + superheated steam on each inner wall is heated to the optimum temperature, aiming for ultra high pressure combustion (4Q) near the center oxygen fuel combustion over 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence water injection section (88L) that heats and injects superheated steam (50) including superheated steam received from a combustion flow inner wall (5d) high-temperature water heating pipe (5H) by combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water injection unit (88L) that receives cheaper liquid oxygen (5K), and also injects the air (28a) into the optimum location of the suction injection flow, and also has a plurality of streamlined ultrahigh pressure combustion aiming combustion chambers (4Q). Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water injection section (4Q) that receives cheaper liquid oxygen (5K) + electricity, and also has a plurality of streamlined ultra-high pressure combustion aimed at air (28a) suction injection flow optimal location (combustion injection as well) 88L), various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined water that receives cheaper liquid oxygen (5K) + electricity + hot water, and also has a plurality of streamlined ultra-high pressure combustion aimed at air (28a) suction injection flow optimum place, as well as combustion injection as well. Various energy storage cycle coalescence engine and coalescence method in the injection section (88L).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) and expand the air inlet to the oxygen coalescence water injection section (88L).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity and have an oxygen coalescence water injection section (88L) that expands the air inlet forward.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity + high-temperature water, and have an oxygen coalescence water injection section (88L) that expands the air inlet forward.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K), make an oxygen coalescence water injection section (88L), expand the air inlet forward, approach the straight line, and inject the bubbles to the bottom of the ship at the maximum.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity, make the oxygen coalescence water injection part (88L) expand the air inlet forward, approach the straight line, and inject the bubbles to the bottom of the ship at the maximum .   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engine that receives cheaper liquid oxygen (5K) + electricity + high temperature water, oxygen combined water injection part (88L), expands the air inlet forward, approaches the straight line, and injects bubbles to the bottom of the ship at the maximum And coalescing method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + hot water, oxygen combined water injection part (88L), expanding the air inlet forward and approaching a straight line, various energy storage cycle combined engines and combined injection Method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), various energy in the combined combustion air (88B) of the combustion gas (49) injection acceleration injection with a plurality of serial combustion chambers (4Q) aiming at ultra-high pressure combustion and streamlined Storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity and using a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion as a streamline type, a plurality of in-line combustion gas (49) injection acceleration oxygen injection air injection unit (88B) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, a theoretical combustion chamber (4Q) aimed at ultra-high pressure combustion is streamlined, and a plurality of in-line combustion gas (49) injection acceleration oxygen combined air injection unit (88B) ) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion is streamlined, and combustion gas (49) is provided in series with (4Q) inner wall or combustion flow inner wall (5d) oxygen + fuel + Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence air injection unit (88B) that uses superheated steam heated at an optimum temperature.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, the combustion chamber (4) with a plurality of in-line combustion gas (49) with a streamlined theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion (4Q) inner wall and combustion flow inner wall (5d) oxygen Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence air injection unit (88B) that uses + fuel + superheated steam heated to an optimum temperature.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Received less expensive liquid oxygen (5K) + electricity + hot water, and the combustion chamber (4Q) and combustion flow inner wall (5d ) Oxygen + fuel + superheated steam heated at an optimum temperature and used as an oxygen coalesced air injection unit (88B) and various energy storage cycle coalescing engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), a theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion is streamlined, and combustion gas (49) is provided in series with (4Q) inner wall or combustion flow inner wall (5d) oxygen + fuel + Various energy storage cycle coalescence engine and coalescence method in the oxygen coalescence air injection section (88B) for heating the superheated steam to the optimum temperature to make the combustion chamber (4Q) combustion aiming at ultra high pressure combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity, the combustion chamber (4) with a plurality of in-line combustion gas (49) with a streamlined theoretical combustion chamber (4Q) aiming at ultra-high pressure combustion (4Q) inner wall and combustion flow inner wall (5d) oxygen + Energy storage cycle coalescence engine and coalescence method in the oxygen coalescence air injection part (88B) for the combustion of the theoretical combustion chamber (4Q) aiming at super high pressure combustion by heating the fuel + superheated steam at the optimum temperature.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Received less expensive liquid oxygen (5K) + electricity + hot water, and the combustion chamber (4Q) and combustion flow inner wall (5d ) Oxygen + fuel + superheated steam is heated to an optimal temperature to achieve super high pressure combustion, and a theoretical combustion chamber (4Q) combustion or the like, which is an oxygen coalescence air injection unit (88B) and various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + hot water, the combustion chamber (4Q) and the combustion flow inner wall (5d) of the combustion gas (49) equipped with a plurality of in-line combustion chambers (4Q) aiming at ultra-high pressure combustion. Various energy storage cycle coalescence engine and coalescence method in the oxygen coalescence air injection part (88B) that makes the superheated steam containing oxygen + fuel + received high temperature water to the optimum temperature by heating it to the ideal combustion chamber (4Q) combustion etc. .   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen + fuel + superheated steam at the optimum temperature on each inner wall and aiming for ultra high pressure combustion in the theoretical combustion chamber (4Q) near the center Oxyfuel combustion Overheated at 3000 ° C or more with multiple combustion Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence air injection unit (88B) aimed at steam suction pyrolysis electrolysis.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and heats the oxygen + fuel + superheated steam at the optimum temperature on each inner wall to aim at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods in the oxygen coalescence air injection part (88B) aimed at superheated steam suction pyrolysis electrolysis.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam on each inner wall at the optimum temperature and aiming for ultra high pressure combustion Oxyfuel combustion near the center of combustion chamber (4Q) 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in the oxygen coalescence air injection part (88B) aimed at superheated steam suction pyrolysis electrolysis by multiple combustion as described above.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) and heating oxygen + fuel + superheated steam at the optimum temperature on each inner wall and aiming for ultra high pressure combustion in the theoretical combustion chamber (4Q) near the center Oxyfuel combustion Overheated at 3000 ° C or more with multiple combustion Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence air injection unit (88B) aimed at steam suction pyrolysis electrolysis oxygen hydrogen hydrogen increase combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and heats the oxygen + fuel + superheated steam at the optimum temperature on each inner wall to aim at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence air injection part (88B) aimed at superheated steam suction pyrolysis electrolysis oxygen oxygen hydrogen augmentation combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam on each inner wall at the optimum temperature and aiming for ultra high pressure combustion Oxyfuel combustion near the center of combustion chamber (4Q) 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in the oxygen coalescence air injection unit (88B) aimed at combustion with superheated steam suction pyrolysis electrolysis oxygen oxygen hydrogen increase combustion by multiple combustion as described above.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K), the oxygen + fuel + superheated steam is heated at the optimum temperature on each inner wall, aiming at ultra high pressure combustion, near the center of the combustion chamber (4Q) Oxyfuel combustion near 3000 ° C and burning at multiple temperatures Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalesced air injection section (88B) that heat-inject superheated steam (50) of a flow inner wall (5d) high-temperature water heating pipe (5H).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Theoretical combustion chamber (4Q) that receives cheaper liquid oxygen (5K) + electricity and heats the oxygen + fuel + superheated steam at the optimum temperature on each inner wall to aim at ultra high pressure combustion. Various energy storage cycle coalescence engines and coalescence methods in which an oxygen coalescence air injection section (88B) that heats and injects superheated steam (50) of a combustion flow inner wall (5d) high-temperature water heating pipe (5H).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam on each inner wall at the optimum temperature and aiming for ultra high pressure combustion Oxyfuel combustion near the center of combustion chamber (4Q) 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in the oxygen coalescence air injection section (88B) for heating and injecting the superheated steam (50) of the combustion flow inner wall (5d) high-temperature water heating pipe (5H) by multiple combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper liquid oxygen (5K) + high-temperature water, oxygen + fuel + superheated steam on each inner wall is heated to the optimum temperature, aiming for ultra high pressure combustion (4Q) near the center oxygen fuel combustion over 3000 ° C Various energy storage cycle coalescence engines and coalescence methods in an oxygen coalescence air injection section (88B) that heats and injects superheated steam (50) including superheated steam received from a combustion flow inner wall (5d) high-temperature water heating pipe (5H) by combustion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air injection unit (88B) that receives cheaper liquid oxygen (5K), and also injects combustion into the air (28a) at the optimum location of the suction injection flow, as well as a theoretical combustion chamber (4Q) aiming at a streamlined ultrahigh pressure combustion. Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air injection unit that receives cheaper liquid oxygen (5K) + electricity, and also injects the air (28a) into the optimum location of the suction injection flow, and has a plurality of streamline type ultra high pressure combustion aiming combustion chambers (4Q). 88B), various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Oxygen combined air that receives cheaper liquid oxygen (5K) + electricity + hot water, and also burns and injects air (28a) to the optimum location of the suction injection flow as well as a plurality of theoretical combustion chambers (4Q) aiming at super high pressure combustion Various energy storage cycle coalescence engines and coalescence methods in the injection section (88B).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) and rotate the oxygen coalescence air injection section (88B) to enable vertical ascent and descent.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity and rotate the oxygen coalescence air injection section (88B) to enable vertical ascent and descent.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods which receive cheaper liquid oxygen (5K) + electricity + high temperature water and rotate the oxygen coalescence air injection section (88B) to enable vertical ascent and descent.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) and rotate the oxygen coalescence air injection section (88B) to enable reverse injection.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity and rotate the oxygen coalescence air injection section (88B) to enable reverse injection.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity + hot water and rotate the oxygen coalescence air injection section (88B) to enable reverse injection.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + high temperature water and rotate the oxygen coalescence air injection section (88B) to enable reverse injection.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity + high-temperature water (52b), and saving various energy as an electrically driven theoretical gas compressor (3T) that compresses gas from the outer peripheral large compression blade to the central short compression blade whose volume is inversely proportional to the pressure Cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engine and coalescence method as an electrically driven theoretical gas compressor (3T) that receives cheaper electricity and compresses the gas volume from the outer peripheral large compression blades to the central short compression blades in inverse proportion to the pressure .   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines that receive less expensive electricity + superheated steam and compress the gas volume from the outer peripheral large compression blades to the central short compression blades in inverse proportion to the pressure to the central short compression blades (3T) And coalescing method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity + hot water (52b), and sucking and compressing air as an electrically driven theoretical gas compressor (3T) that compresses gas from the outer peripheral long compression blade to the central short compression blade with the gas volume inversely proportional to the pressure Various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Combined with various energy conservation cycles to receive and compress air as an electrically driven theoretical gas compressor (3T) that receives cheaper electricity and compresses the gas volume from the outer peripheral large compression blades to the central short compression blades in inverse proportion to the pressure Organization and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various types of energy that sucks and compresses air as an electrically driven theoretical gas compressor (3T) that receives cheaper electricity + superheated steam and compresses the gas volume from the outer peripheral large compression blades to the central short compression blades, which are aimed at inversely proportional to the pressure. Storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity + hot water (52b), and sucking and compressing air as an electrically driven theoretical gas compressor (3T) that compresses gas from the outer peripheral long compression blade to the central short compression blade with the gas volume inversely proportional to the pressure Various energy storage cycle coalescence engine and coalescence method for producing heat exchange superheated steam.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity and producing compressed heat exchange superheated steam by sucking air as an electrically driven theoretical gas compressor (3T) that compresses gas volume from the outer peripheral long compression blades aiming inversely proportional to pressure to the central short compression blades Various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As the electrically driven theoretical gas compressor (3T) that receives cheaper electricity + superheated steam and compresses the gas volume from the outer peripheral large compression blades to the central short compression blades in inverse proportion to the pressure, it sucks air by suction compression heat exchange overheating Various energy storage cycle coalescence engine and coalescence method for producing steam.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Air as an electrically driven theoretical gas compressor (3T) that receives cheaper electricity + high-temperature water (52b) + superheated steam and compresses the gas volume from the outer peripheral long compression blades to the central short compression blades, with the gas volume inversely proportional to the pressure. Various energy storage cycle coalescence engine and coalescence method for producing suction compression heat exchange superheated steam.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity + hot water (52b), and sucking and compressing air as an electrically driven theoretical gas compressor (3T) that compresses gas from the outer peripheral long compression blade to the central short compression blade with the gas volume inversely proportional to the pressure Various energy storage cycle coalescence engine and coalescence method for producing superheated steam with a compressed air heat exchanger (2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As an electrically driven theoretical gas compressor (3T) that receives cheaper electricity and compresses the gas volume from the outer circumferential large compression blades to the central short compression blades in an inverse proportion to the pressure, the air is sucked into compressed air. 2Y) Various energy storage cycle coalescence engines and coalescence methods for producing superheated steam.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As an electrically driven theoretical gas compressor (3T) that receives cheaper electricity + superheated steam and compresses the gas volume from the outer peripheral long compression blades to the central short compression blades with the gas volume inversely proportional to the pressure, the air is sucked compressed compressed air heat Various energy storage cycle coalescence engine and coalescence method for producing superheated steam with an exchanger (2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity + hot water (52b), and sucking and compressing air as an electrically driven theoretical gas compressor (3T) that compresses gas from the outer peripheral long compression blade to the central short compression blade with the gas volume inversely proportional to the pressure Various energy storage cycle coalescence engines and coalescence methods for supplying superheated steam to the production supply facility (3D) with a compressed air heat exchanger (2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As an electrically driven theoretical gas compressor (3T) that receives cheaper electricity and compresses the gas volume from the outer circumferential large compression blades to the central short compression blades in an inverse proportion to the pressure, the air is sucked into compressed air. 2Y) Various energy storage cycle coalescence engines and coalescence methods for supplying superheated steam to the production supply facility (3D).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As an electrically driven theoretical gas compressor (3T) that receives cheaper electricity + superheated steam and compresses the gas volume from the outer peripheral long compression blades to the central short compression blades with the gas volume inversely proportional to the pressure, the air is sucked compressed compressed air heat Various energy storage cycle coalescence engines and coalescence methods for supplying superheated steam to the production supply facility (3D) with the exchanger (2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving cheaper electricity + hot water (52b), and sucking and compressing air as an electrically driven theoretical gas compressor (3T) that compresses gas from the outer peripheral long compression blade to the central short compression blade with the gas volume inversely proportional to the pressure Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) with the compressed air heat exchanger (2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As an electrically driven theoretical gas compressor (3T) that receives cheaper electricity and compresses the gas volume from the outer circumferential large compression blades to the central short compression blades in an inverse proportion to the pressure, the air is sucked into compressed air. 2Y) Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) in 2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) As an electrically driven theoretical gas compressor (3T) that receives cheaper electricity + superheated steam and compresses the gas volume from the outer peripheral long compression blades to the central short compression blades with the gas volume inversely proportional to the pressure, the air is sucked compressed compressed air heat Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) with the exchanger (2Y).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Air as an electrically driven theoretical gas compressor (3T) that receives cheaper electricity + high-temperature water (52b) + superheated steam and compresses the gas volume from the outer peripheral long compression blades to the central short compression blades, with the gas volume inversely proportional to the pressure. Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) with a suction compressed air heat exchanger (2Y).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods configured to compress from the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for compressing air as a configuration for compressing the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy conservation cycle coalescence engines and coalescence methods for compressing air (28a) as a configuration for compressing the outer peripheral long compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for compressing air (28a) from the outer circumference to the suction center as a configuration in which the outer circumference large compression blade (8) is compressed to the center short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for heating air (28a) compressed water from the outer circumference to the suction center as a configuration for compressing from the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods in which air (28a) compressed high-temperature water is heated from the outer circumference to the suction center as a configuration for compressing from the outer peripheral long compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for heating air (28a) compressed superheated steam from the outer circumference to the suction center as a configuration for compressing from the outer circumference long large compression blade (8) to the center short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines that heat water from the outer circumference to the suction center from the outer circumference long compression blade (8) to the center short compression blade (8) with air (28a) compressed and compressed air heat exchanger (2Y); Merge method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle combined engines that heat high-temperature water from the outer periphery to the suction center with the air (28a) from the outer peripheral long compression blade (8) to the central short compression blade (8) by the compressed compression air heat exchanger (2Y) And coalescing method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engine which heats superheated steam with air (28a) compression compressed air heat exchanger (2Y) from the outer circumference to the suction center from the outer circumference as a structure to compress from the outer circumference long compression blade (8) to the center short compression blade (8) And coalescing method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing compressed air + superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing high-pressure compressed air + high-pressure superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing ultra-high pressure compressed air + ultra-high pressure superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing the outer peripheral large compression blade (8) to the central short compression blade (8).   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines that supply compressed air + superheated steam production and supply equipment (3D) with a compressed air heat exchanger (2Y) as a configuration that compresses from the outer peripheral large compression blade (8) to the central short compression blade (8), and Merge method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Combined with various energy storage cycles to supply high pressure compressed air + high pressure superheated steam production and supply equipment (3D) with compressed air heat exchanger (2Y) as a configuration for compressing from outer peripheral large compression blade (8) to central short compression blade (8) Organization and coalescence method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various types of energy storage to supply ultra high pressure compressed air + ultra high pressure superheated steam production and supply equipment (3D) with compressed air heat exchanger (2Y) as a configuration to compress from the outer peripheral large compression blade (8) to the central short compression blade (8) Cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Combined with various energy storage cycles to supply liquid air + super high pressure superheated steam production and supply equipment (3D) with compressed air heat exchanger (2Y) as a configuration to compress from the outer peripheral long compression blade (8) to the central short compression blade (8) Organization and coalescence method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure Various types of energy supplied to the production / supply facility (3D) of liquid oxygen + liquid nitrogen + super high pressure superheated steam by the compressed air heat exchanger (2Y) as a structure for compressing the outer peripheral large compression blade (8) to the central short compression blade (8) Storage cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super high speed circumferential speed vertical blade hydrogravity turbine (8P) Extremely inexpensive power generation electric drive, theoretical gas compressor (3T) as gas volume is inversely proportional to pressure The compressed air heat exchanger (2Y) is used to compress electricity + liquid oxygen + liquid nitrogen + super high pressure superheated steam production and supply equipment (3D) as a configuration for compressing the outer peripheral large compression blade (8) to the central short compression blade (8). Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engine which receives cheaper liquid oxygen (5K) and injects and burns fuel and injects and burns fuel from multiple points (8d) extended upper expansion blade groups (8d) in the circumferential expansion process of 380 degrees And coalescing method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy conservation cycles in which fuel oxygen (5K) + electricity is received and injected and burned, and fuel is injected and burned from a plurality of locations in the fuel pipe (25a) extended upper expansion blade group (8d) in the circumferential expansion process of 380 degrees Merger engine and merger method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various types of fuel injection / combustion by receiving fuel oxygen (5K) + electricity + high temperature water and injecting and burning from a plurality of locations on the upper expansion blade group (8d) of the upper upper expansion blade group (8d) in the expansion process of 380 degrees in the circumferential direction. Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Receiving less expensive liquid oxygen (5K) and fuel-injecting combustion, in the process of expansion of 380 degrees in the circumferential direction, various types of energy storage to increase the fuel-injection / combustion combustion quantity from multiple points of the fuel pipe (25a) extended upper expansion blade group (8d) Cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various types of fuel injection combustion combustion is received from fuel oxygen (5K) + electricity, and fuel injection combustion combustion is increased from a plurality of locations in the fuel pipe (25a) extended upper expansion blade group (8d) in the circumferential expansion process of 380 degrees. Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Fuel injection combustion with receiving low-priced liquid oxygen (5K) + electricity + high-temperature water, and fuel injection combustion combustion amount from multiple locations of the fuel pipe (25a) extended upper expansion blade group (8d) in the circumferential expansion process of 380 degrees Various energy conservation cycle coalescence engines and coalescence methods to increase.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods in which cheaper liquid oxygen (5K) is received and injected and burned and compressed with the turbine outer casing (77a) in the circumferential direction of 380 degrees expansion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescing engines and coalescence methods which receive cheaper liquid oxygen (5K) + electricity and inject and burn fuel and compress air with the turbine outer casing (77a) in the circumferential direction of 380 degrees expansion.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence that receive and inject and burn cheaper liquid oxygen (5K) + electricity + high temperature water and compress air with the turbine outer box (77a) in the circumferential expansion process of 380 degrees Method.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Various energy storage cycle coalescence engines and coalescence methods in which cheaper liquid oxygen (5K) + high temperature water is received and injected and burned, and compressed with the turbine outer casing (77a) in the circumferential expansion process of 380 degrees.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Cheaper liquid oxygen (5K) is received and injected and combusted, and compressed in the compressed air section (9D) with the turbine outer casing (77a) in the circumferential direction of 380 degrees expansion, and air injection nozzle (5) Various energy storage cycle coalescence engines and coalescence methods for injecting at multiple locations   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Cheaper liquid oxygen (5K) + electricity is received and injected and burned, and in the expansion process of 380 degrees in the circumferential direction, compressed air (9D) is compressed between the turbine outer box (77a) and air injection nozzle ( 5) Various energy conservation cycle coalescence engines and coalescence methods for injecting at multiple locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Cheaper liquid oxygen (5K) + electricity + high-temperature water is received and injected and burned, and compressed air (9D) is compressed between the turbine outer box (77a) and compressed in the circumferential direction of 380 degrees. Injection nozzle (5) Various energy storage cycle coalescence engine and coalescence method for injecting a plurality of locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Cheaper liquid oxygen (5K) is received and injected and combusted, and compressed in the compressed air section (9D) with the turbine outer casing (77a) in the circumferential direction of 380 degrees expansion, and air injection nozzle (5) Various energy storage cycle coalescing engines and coalescence methods for a theoretical expansion engine (3Q) that increases the amount of fuel injected at multiple locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Cheaper liquid oxygen (5K) + electricity is received and injected and burned, and in the expansion process of 380 degrees in the circumferential direction, compressed air (9D) is compressed between the turbine outer box (77a) and air injection nozzle ( 5) Various energy storage cycle coalescence engines and coalescence methods that increase the amount of fuel injected at multiple locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Cheaper liquid oxygen (5K) + electricity + high-temperature water is received and injected and burned, and compressed air (9D) is compressed between the turbine outer box (77a) and compressed in the circumferential direction of 380 degrees. Injection nozzle (5) Various energy storage cycle coalescence engine and coalescence method for increasing the amount of fuel burned at multiple locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Lower cost liquid oxygen (5K) is received and injected and burned, and in the process of expansion of 380 degrees in the circumferential direction, fuel is injected and burned from a plurality of locations in the fuel pipe (25a) extended upper expansion blade group (8d), and the turbine outer casing (77a ) And compressed air section (9D) to compress the air, and the air injection nozzle (5) various energy storage cycle coalescing engine and coalescence method for increasing the amount of fuel injected at multiple locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Lower cost liquid oxygen (5K) + electricity is received and injected and burned, and in the process of expansion of 380 degrees in the circumferential direction, the fuel pipe (25a) and the extended upper expansion blade group (8d) are injected and burned from a plurality of locations. (77a) Various energy storage cycle coalescing engines and coalescence methods that compress the compressed air portion (9D) and air injection nozzles (5) to increase the fuel combustion quantity at multiple locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Fuel oxygen injection (5K) + electricity + high-temperature water is received and injected and burned, and in the expansion process in the circumferential direction of 380 degrees, the fuel pipe (25a) and the upper expansion blade group (8d) are injected and burned from a plurality of locations. Various energy storage cycle coalescence engines and coalescence methods in which the compressed air portion (9D) is compressed between the turbine outer box (77a) and the air injection nozzle (5) increases the fuel combustion amount at a plurality of locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 and super-high speed circumferential speed (8P) Electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) Fuel oxygen injection (5K) + high temperature water is received and injected and burned, and in the process of expansion of 380 degrees in the circumferential direction, the fuel pipe (25a) and the extended upper expansion blade group (8d) are injected and burned from a plurality of locations. Various energy storage cycle coalescence engines and coalescence methods in which the compressed air portion (9D) is compressed between the box (77a) and the air injection nozzle (5) increases the fuel combustion amount at a plurality of locations.   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 + super high speed circumferential speed Water sprayed vertically under ultra-high pressure in vacuum, accelerated by gravitational acceleration, cylinder inner blade group (60C) and cylinder outer Various energy storage cycle coalescence engines and coalescence methods for generating power as a turbine utilizing magnetic force that double-rotates the blade group (60D).   Vertically moving blade water gravity turbine (8P) with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Water sprayed vertically below the ultra-high pressure in the vacuum and accelerated by gravitational acceleration, and a plurality of inner rotor blade groups (60C) inside the cylinder Various energy storage cycle coalescence engines and coalescence methods for generating electricity as a turbine utilizing magnetic force that double-reverses a cylindrical outer blade group (60D).   Vertically moving blade water gravity turbine (8P) with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Water sprayed vertically below the ultra-high pressure in the vacuum and accelerated by gravitational acceleration, and a plurality of inner rotor blade groups (60C) inside the cylinder Various energy storage cycle coalescence engines and coalescence methods for generating electricity as a large number of turbines utilizing magnetic force to double-reverse cylindrical outer blade groups (60D).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 + super high speed circumferential speed Water sprayed vertically under ultra-high pressure in vacuum, accelerated by gravitational acceleration, cylinder inner blade group (60C) and cylinder outer Various energy storage cycle coalescence engine and coalescence method for generating power as a turbine utilizing magnetic force in which a rotor blade group (60D) is double-reversed by a double reversal magnetic device (85).   Vertically moving blade water gravity turbine (8P) with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Water sprayed vertically below the ultra-high pressure in the vacuum and accelerated by gravitational acceleration, and a plurality of inner rotor blade groups (60C) inside the cylinder Various energy storage cycle coalescence engine and coalescence method for generating electricity as a turbine utilizing magnetic force in which a cylindrical outer blade group (60D) is double-reversed by a double reversal magnetic device (85).   Vertically moving blade water gravity turbine (8P) with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Water sprayed vertically below the ultra-high pressure in the vacuum and accelerated by gravitational acceleration, and a plurality of inner rotor blade groups (60C) inside the cylinder Various energy storage cycle coalescence engines and coalescence methods for generating electricity as a large number of turbines using magnetic force that double-reverses the outer cylindrical blade group (60D) with a contra-rotating magnetic device (85).   Vertically moving blade water gravity turbine (8P) with magnetism bearing load approaching 0 + super high speed circumferential speed Water sprayed vertically under ultra-high pressure in vacuum, accelerated by gravitational acceleration, cylinder inner blade group (60C) and cylinder outer Various energy storage cycle coalescence engines and coalescence methods for generating power as a weight-supported magnetic force turbine in which the rotor blade group (60D) is double-inverted by a double-inversion magnetic device (85).   Vertically moving blade water gravity turbine (8P) with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Water sprayed vertically below the ultra-high pressure in the vacuum and accelerated by gravitational acceleration, and a plurality of inner rotor blade groups (60C) inside the cylinder Various energy storage cycle coalescence engines and coalescence methods for generating electricity as a weight-supported magnetic force turbine in which a cylindrical outer blade group (60D) is double-reversed by a double reversal magnetic device (85).   Vertically moving blade water gravity turbine (8P) with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Water sprayed vertically below the ultra-high pressure in the vacuum and accelerated by gravitational acceleration, and a plurality of inner rotor blade groups (60C) inside the cylinder Various energy storage cycle coalescence engines and coalescence methods for generating electricity as a large number of turbines using a magnetic force such as weight support in which a cylindrical outer blade group (60D) is double-reversed by a double reversal magnetic device (85).   Various energy conservation cycles driven by oxygen combined water injection unit (88L) as vertical type moving blade water gravity turbine (8P) power generation electric product + rocket combustion + jet combustion with magnetic bearing load approaching 0 + super high speed circumferential speed Merger engine and merger method.   Oxygen combined water injection unit (88L) is driven as a vertical all-blade water gravity turbine (8P) power generation electric product + 2 rocket combustion + 2 jet combustion 2 locations with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined water injection unit (88L) is driven as a vertical all-blade water gravity turbine (8P) power generation electric product + 3 rocket combustions + 3 jet combustions with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed. Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined water injection unit (88L) is driven as a vertical all-blade water gravity turbine (8P) power generation electric product + 4 rocket combustion + 4 jet combustion 4 locations with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined water injection unit (88L) is driven as a vertical all-blade water gravity turbine (8P) power generation electric product + 5 rocket combustion + 5 jet combustion locations with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined water injection unit (88L) is driven as a vertical all-blade water gravity turbine (8P) power generation electric product + 6 rocket combustions + 6 jet combustions with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Various energy storage cycles driven by oxygen combined air injection part (88B) as vertical type moving blade water gravity turbine (8P) power generation electric product + rocket combustion + jet combustion with magnetic bearing load approaching 0 + super high speed circumferential speed Merger engine and merger method.   Oxygen combined air injection unit (88B) is driven as a vertical all-blade hydrogravity turbine (8P) power generation electric product + two rocket combustions + two jet combustions with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined air injection unit (88B) is driven as a vertical all-blade hydrogravity turbine (8P) power generation electric product + 3 rocket combustion + 3 jet jets with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined air injection unit (88B) is driven as a vertical all-blade water gravity turbine (8P) power generation electric product + 4 rocket combustion + 4 jet combustion 4 locations with magnetic utilization bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined air injection unit (88B) is driven as a vertical all-blade hydrogravity turbine (8P) power generation electric product + 5 rocket combustion + 5 jet combustion locations with magnetically approaching bearing load 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Oxygen combined air injection unit (88B) is driven as a vertical all-blade hydrogravity turbine (8P) power generation electric product + 6 rocket combustion + 6 jet combustion locations with magnetic utilization bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Vertical type moving blade water gravity turbine (8P) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) of extremely low-cost power generation electricity production, oxygen combined water injection Various energy storage cycle coalescing engine and coalescence method in which the maximum bubbles are jetted into the ship bottom vertical parallel plate (9Q) in the part (88L) driven oxygen coalescence injection ship (39R).   Vertical type moving blade water gravity turbine (8P) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) of extremely low-cost power generation electricity production, oxygen combined water injection (88L) driven oxygen coalescence screw injection ship (39S), various energy storage cycle coalescence engine and coalescence method for injecting the maximum amount of bubbles into the bottom vertical parallel plate (9Q).   Vertical type moving blade water gravity turbine (8P) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) of extremely low-cost power generation electricity production, oxygen combined water injection (88L) Driven oxygen coalescence injection ship (39R), various bottom-up vertical parallel plates (9Q) wide, and various energy storage cycle coalescence engines and coalescence methods that maximize the air floating amount.   Vertical type moving blade water gravity turbine (8P) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) of extremely low-cost power generation electricity production, oxygen combined water injection Part (88L) driven oxygen coalescence screw injection ship (39S), and various energy storage cycle coalescence engines and coalescence methods that have a wide bottom bottom parallel plate (9Q) to maximize the air floating amount.   Vertical type moving blade water gravity turbine (8P) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) of extremely low-cost power generation electricity production, oxygen combined water injection Various energy storage cycle coalescence engines and coalescence methods that maximize the friction reduction by making the part (88L) driven oxygen coalescence injection ship (39R) wide in the bottom vertical parallel plate (9Q).   Vertical type moving blade water gravity turbine (8P) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D) of extremely low-cost power generation electricity production, oxygen combined water injection Part (88L) driven oxygen coalescence screw injection ship (39S), and various energy conservation cycle coalescence engines and coalescence methods for providing a bottom vertical parallel plate (9Q) wide to maximize friction reduction.